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Testing av regulator for små turbiner
Øystein S Hveem
Master of Energy and Environmental Engineering
Supervisor: Torbjørn Kristian Nielsen, EPT
Department of Energy and Process Engineering
Submission date: September 2013
Norwegian University of Science and Technology
Acknowledgement
The present work is carried out at the Department of Energy and Process Engi-neering at the Norwegian University of Science and Technology as my master thesisfall 2013.
It has been a pleasure to work with the thesis at the Waterpower Laboratory. Iwould like to thank the staff and the students at the laboratory for feedback, gooddiscussions and support.
First of all, I would like to thank my supervisor Professor Torbjørn K.Nielsen forsupporting me during the thesis. Anders Austegard deserves a great thank foralways being available to answer my questions. A special thank is given to thetechnicians in the laboratory with Joar Grilstad, Halvor Haukvik and Trygve Op-land that have done an incredible job. Without their help, the test rig would neverhave been installed. Chiyembekezo Kaunda deserves thanks for helping me duringthe testing in the laboratory. Finally I would like to thank Bjørn Winther Solemslieand Peter Joachim Gogstad for technical support and good discussions during themaster thesis.
Øystein Sveinsgjerd HveemTrondheim, September 26, 2013
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Samandrag
Denne masteroppgava beskriv installasjon og testing av ein vasskraftmodell tilkoplaeit frittstaende kraftsystem. Modellen vart installert i Vannkraftlaboratoriet vedNTNU og bestod av ein tverrstrømturbin, ein synkrongenerator og ei enkel last-kontroll-reguleringseining (ELC) produsert av Remote HydroLight i Afghanistan.Malsetjinga med forsøka var a evaluera eigenskapane til kontrollsystemet mtp spran-grespons i frekvens og generatorspenning. Kontrolleininga nytta fasevinkelreguler-ing og fleire halvleiarar (triacar) for a leia overskuddseffekt fra generatoren tildumplastar. Dumplastane var varmekolbar som var montert og senka ned i det ne-dre reservoaret i laboratoriet. Ei tilsvarande konfigurasjon med varmekolbar vartnytta for a simulera variabel forbrukslast i energisystemet. Fleire testar vart utførtfor a evaluera eigenskapane til kontrollsystemet. Det svake leddet i testriggen varutvekslinga med beltedrift, som under testinga byrja a slure. Dette førte til ei aukei turtalet pa turbinen og reduserte kvaliteten pa resultata. Under bra tilkopling ogfrakopling av full last vart det oppdaga eit enkelt kraftig sprang bade i frekvens oggeneratorspenning. Dette signalet kan forstyrra og skada sensitive elektriske ap-parat. Trass dette, var responsen til kontrollsystemet god under dei ulike testanemed stabil regulering i bade spenning og frekvens.
I oppgava blir det foreslatt a implementere pulsbredde-modulasjon for a eliminereden ugunstige paverknaden fra halvleiarane i generatorspenningssignalet. Dennemodifikasjonen gjev auka fleksibilitet i energisystemet ved a opna for bruk av in-duktive eller konduktive lastar som til dømes ein batteribank.
I oppgava er det skildra eit frittstaande hybridenergisystem der eksisterande testrigger kopla til eit solcellepanel, medan eit meir sofistikert oppsett er skildra for meirkomplekse energisystem. Begge systema er basert pa ein felles likestraumskrins oglading av ein batteribank. Dette fører til eit meir fleksibelt, paliteleg og stabiltenergisystem.
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Abstract
In this master thesis, an experimental setup for a stand-alone power system hasbeen installed and tested in the Waterpower Laboratory at NTNU. The experimen-tal test rig consisted of a cross-flow turbine, a synchronous generator and an elec-tronic load controller (ELC) manufactured by Remote HydroLight in Afghanistan.The objective of the experiments was to evaluate the performance of the ELCregarding step response in frequency and generator voltage. The controller usedphase angle regulation and triacs to divert excess energy to dump loads. The dumploads were heating elements installed and submerged in the lower reservoir in thelaboratory. A similar configuration was installed for varying the user load in theenergy system. Several tests were performed to evaluate the performance of theELC. A weak component in the test rig was the transmission system that startedto slip. This resulted in an increase in turbine speed during the experiment andreduced the quality of the results. However, the tests indicated that a rapid singlepeak appears during abrupt disconnection and connection of loads. This may dis-turb and damage sensitive electronic equipment. Despite this, the ELC performedwell during the diffent tests with stable regulation in voltage and frequency.
Introducing pulse width modulation would eliminate the unfavorable influence ofthe triacs in the generator voltage signal. With this modification it is possible toincrease the flexibility in the energy system by introducing inductive or conductiveloads like a battery bank.
A hybrid stand alone energy system connecting existing test rig with a photovoltaic-module has been developed. For a larger and more complex energy system, a moresophisticated system has been designed. Both systems are based on a commonDC-grid and charging of a battery bank. This results in a more flexible, reliableand a more stable energy system.
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Contents
Nomenclature xv
1 Introduction 1
2 Background 32.1 Cross-flow turbine (Ossberger turbine) . . . . . . . . . . . . . . . . . 32.2 Generator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32.3 Electronic load controller (ELC) . . . . . . . . . . . . . . . . . . . . 42.4 Earlier work . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
3 Theory 73.0.1 Direct Current (DC) and Alternating Current (AC) . . . . . 73.0.2 Mains frequency . . . . . . . . . . . . . . . . . . . . . . . . . 73.0.3 Electric Power . . . . . . . . . . . . . . . . . . . . . . . . . . 83.0.4 RMS-value . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
3.1 Test rig . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103.1.1 Necessary parameters . . . . . . . . . . . . . . . . . . . . . . 103.1.2 Hydraulic power . . . . . . . . . . . . . . . . . . . . . . . . . 10
3.2 Uncertainty analysis . . . . . . . . . . . . . . . . . . . . . . . . . . . 133.2.1 Spurious errors . . . . . . . . . . . . . . . . . . . . . . . . . . 133.2.2 Random errors and related uncertainty . . . . . . . . . . . . 133.2.3 Uncertainty analysis of experiments . . . . . . . . . . . . . . 15
3.3 Governing system - Electronic load controller . . . . . . . . . . . . . 163.3.1 Critical situations . . . . . . . . . . . . . . . . . . . . . . . . 193.3.2 Front panel of the ELC . . . . . . . . . . . . . . . . . . . . . 203.3.3 Inside the ELC . . . . . . . . . . . . . . . . . . . . . . . . . . 223.3.4 Signal distribution . . . . . . . . . . . . . . . . . . . . . . . . 223.3.5 Experience from RHL’s projects . . . . . . . . . . . . . . . . 24
3.4 Improvements of the ELC . . . . . . . . . . . . . . . . . . . . . . . . 263.4.1 Pulse width modulation . . . . . . . . . . . . . . . . . . . . . 263.4.2 Binary loads . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
3.5 Hybrid energy systems . . . . . . . . . . . . . . . . . . . . . . . . . . 283.5.1 Photovoltaic energy . . . . . . . . . . . . . . . . . . . . . . . 283.5.2 Wind energy . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
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3.5.3 Energy from fossil fuel . . . . . . . . . . . . . . . . . . . . . . 283.5.4 Maximum power point tracking . . . . . . . . . . . . . . . . 293.5.5 Inverter, rectifier and DC/DC-converter . . . . . . . . . . . . 303.5.6 Energy management system . . . . . . . . . . . . . . . . . . . 30
3.6 Hybrid energy system for remote areas . . . . . . . . . . . . . . . . . 303.7 Hybrid energy system with ELC . . . . . . . . . . . . . . . . . . . . 31
4 Instrumentation 334.1 Experimental setup . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
4.1.1 IAM-turbine . . . . . . . . . . . . . . . . . . . . . . . . . . . 364.1.2 Generator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 364.1.3 Electronic load controller . . . . . . . . . . . . . . . . . . . . 374.1.4 Dump load system . . . . . . . . . . . . . . . . . . . . . . . . 374.1.5 Consumption load system . . . . . . . . . . . . . . . . . . . . 38
4.2 Measurements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 394.2.1 Logging instrument - IAM-turbine . . . . . . . . . . . . . . . 394.2.2 Inlet pressure . . . . . . . . . . . . . . . . . . . . . . . . . . . 394.2.3 Discharge . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 394.2.4 Rotational speed . . . . . . . . . . . . . . . . . . . . . . . . . 404.2.5 Water temperature . . . . . . . . . . . . . . . . . . . . . . . . 414.2.6 Temperature - ELC . . . . . . . . . . . . . . . . . . . . . . . 41
4.3 Generator- and dump load system . . . . . . . . . . . . . . . . . . . 414.3.1 Logging instruments . . . . . . . . . . . . . . . . . . . . . . . 414.3.2 Measurements . . . . . . . . . . . . . . . . . . . . . . . . . . 41
5 Method 435.1 Calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
5.1.1 Inlet pressure . . . . . . . . . . . . . . . . . . . . . . . . . . . 435.1.2 Discharge . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
5.2 Procedure for experiments . . . . . . . . . . . . . . . . . . . . . . . . 455.2.1 Power test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 455.2.2 Rapid on-load situation . . . . . . . . . . . . . . . . . . . . . 455.2.3 Rapid off-load situation . . . . . . . . . . . . . . . . . . . . . 455.2.4 Overload signal/undervoltage . . . . . . . . . . . . . . . . . . 455.2.5 Run-away test . . . . . . . . . . . . . . . . . . . . . . . . . . 46
6 Results 476.1 Performance of the experimental test rig . . . . . . . . . . . . . . . . 486.2 Performance of the ELC . . . . . . . . . . . . . . . . . . . . . . . . . 49
6.2.1 Power test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 496.2.2 Rapid on-load situation . . . . . . . . . . . . . . . . . . . . . 516.2.3 Rapid off-load situation . . . . . . . . . . . . . . . . . . . . . 526.2.4 Overload signal/undervoltage . . . . . . . . . . . . . . . . . . 536.2.5 Run-away-test . . . . . . . . . . . . . . . . . . . . . . . . . . 57
6.3 Improvements of the Electronic load controller . . . . . . . . . . . . 586.4 Connection with other energy sources . . . . . . . . . . . . . . . . . 58
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7 Discussion 617.1 Performance of the experimental test rig . . . . . . . . . . . . . . . . 617.2 Performance of the ELC . . . . . . . . . . . . . . . . . . . . . . . . . 62
7.2.1 Power test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 627.2.2 Rapid on-load situation . . . . . . . . . . . . . . . . . . . . . 627.2.3 Rapid off-load situation . . . . . . . . . . . . . . . . . . . . . 637.2.4 Overload signal/undervoltage . . . . . . . . . . . . . . . . . . 637.2.5 Run-away-test . . . . . . . . . . . . . . . . . . . . . . . . . . 64
7.3 Improvements of the electronic load controller . . . . . . . . . . . . . 647.4 Connection with other energy sources . . . . . . . . . . . . . . . . . 65
8 Further work 67
9 Conclusion 69
A Calibration 1
B Instrumentation 5B.1 Generator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5B.2 ELC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
B.2.1 Estimated price . . . . . . . . . . . . . . . . . . . . . . . . . . 11B.3 Heating elements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
C Data aquistion-program 17C.1 LabVIEW-program . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
D Experimental data 21
E HSE-repport for experiment 29
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List of Figures
1.0.1 View of Earth from outer space at night . . . . . . . . . . . . . . . . 2
2.1.1 Cross-flow turbine . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
3.0.1 Principle of mains frequency . . . . . . . . . . . . . . . . . . . . . . . 83.0.2 Power triangle . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83.3.3 Principle of electronic load controller . . . . . . . . . . . . . . . . . . 163.3.4 Generator voltage with dump loads triggered at 70 . . . . . . . . . 173.3.5 Electronic load controller developed and manufactured by Remote
HydroLight . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 203.3.6 Water heater used in RHL’s projects . . . . . . . . . . . . . . . . . . 213.3.7 Inside the electronic load controller . . . . . . . . . . . . . . . . . . . 223.3.8 Digital 3-phase PCB used in the experiment . . . . . . . . . . . . . . 233.4.9 Principle of PWM [13] . . . . . . . . . . . . . . . . . . . . . . . . . . 273.4.10Principle of binary loads [15] . . . . . . . . . . . . . . . . . . . . . . 273.5.11MPPT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 293.5.12Wind power plot . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 293.6.13Hybrid energy system for remote areas . . . . . . . . . . . . . . . . . 313.7.14Stand alone hybrid energy system with ELC . . . . . . . . . . . . . . 32
4.1.1 Piping network for cross-flow turbine . . . . . . . . . . . . . . . . . . 344.1.2 Principle of experimental setup . . . . . . . . . . . . . . . . . . . . . 344.1.3 Overview of the experimental test rig . . . . . . . . . . . . . . . . . . 354.1.4 IAM-turbine and synchronous generator with belt drive (behind
black cover) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 364.1.5 Electronic load controller used in experiments . . . . . . . . . . . . . 374.1.6 Dump load and consumption load system . . . . . . . . . . . . . . . 384.2.7 Pressure transducer . . . . . . . . . . . . . . . . . . . . . . . . . . . 404.2.8 Krohne flowmeter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 404.2.9 Optical measurement of rotational speed on turbine . . . . . . . . . 404.2.10Temperature measurements . . . . . . . . . . . . . . . . . . . . . . . 41
5.1.1 Equipment for calibrating pressure transducer . . . . . . . . . . . . . 445.1.2 Rebuilding the piping system for calibration of flow meter . . . . . . 44
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6.0.1 Final test rig . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 486.2.2 Generator and dump load voltage. In this situation 6kW dump
loads and 1kW consumption loads are connected. The resultingtrigger angle is 113 . . . . . . . . . . . . . . . . . . . . . . . . . . . 50
6.2.3 Step response in generator voltage (RMS) . . . . . . . . . . . . . . . 516.2.4 Step response in frequency . . . . . . . . . . . . . . . . . . . . . . . . 516.2.5 Step response in generator voltage (RMS) . . . . . . . . . . . . . . . 526.2.6 Step response in frequency . . . . . . . . . . . . . . . . . . . . . . . . 536.2.7 Step response in generator voltage (RMS) . . . . . . . . . . . . . . . 546.2.8 Step response in frequency . . . . . . . . . . . . . . . . . . . . . . . . 546.2.9 Step response in generator voltage (RMS) . . . . . . . . . . . . . . . 556.2.10Step response in frequency . . . . . . . . . . . . . . . . . . . . . . . . 556.2.11Run-away speed . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57
C.1.1Front panel of LabView program for hydraulic performance. Dueto a very large block diagram it was not possible to view the wholeprogram. See . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
C.1.2Front panel of LabView program (tab 1) for ELC with processing ofdump load- and generator voltage signals. Due to a very large blockdiagram it was not possible to view the whole program . . . . . . . . 19
C.1.3Front panel of LabView program(tab 2) for ELC with only dumpload- and generator voltage signals plotted. Due to a very largeblock diagram it was not possible to view the whole program . . . . 20
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List of Tables
4.2.1 Instruments used in the experiments . . . . . . . . . . . . . . . . . . 39
6.1.1 Parameters in operating point . . . . . . . . . . . . . . . . . . . . . . 496.2.2 Power test - Different load situations . . . . . . . . . . . . . . . . . . 506.2.3 Important parameters registered during the rapid on load situation . 526.2.4 Important parameters registered during the rapid off load situation . 536.2.5 Important parameters registered during overload situation with 1kW 546.2.6 Important parameters registered during overload situation with 2kW 566.2.7 Hydraulic parameters registered before and after the run-away test . 57
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Nomenclature
η hydraulic efficiency, −
ω angular velocity, s−1
ρ density, kg/m3
σm mean standard deviation
fmains mains frequency, Hz
Hn net head, mWc
nED reduced rotational speed
Ph hydraulic power, W
Pm mechanical power, W
QED reduced discharge
A area, m2
D diameter, m
e error
F force, N
g acceleration of gravity, m/s2
I current, A
n rotational speed, RPM
P real power, W
p pressure, Pa
Q reactive power, V Ar
Q volume flow (discharge), m3/s
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R resistance, Ω
S apparent power, V A
s sample standard deviation
V voltage, V
v water velocity, m/s
Abbreviation
AC Alternating current
BEP Best efficiency point
BL Binary loads
DAQ Data acquisition
DC Direct current
ELC Electronic load controller
EMS Energy management system
HSE Health, safe and environmental
IAM International Assistance Mission
IGBT Insulated-gate bipolar transistor
MOSFET Metal oxide semiconductor field effect transistor
MPPT Maximum power point tracking
NTNU Norwegian University of Science and Technology
PV Photovoltaic
PWM Pulse width modulation
RAPS Remote area power supply
RHL Remote HydroLight
RMS Root-mean-square
RSS Root-sum-square
SAPS Stand-alone power system
TMT Traditional Mill Turbine
TRIAC Triode for Alternating Current
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Chapter 1
Introduction
Access to electricity leads to increased welfare and development. [18] When lookingon Earth from the outer space at night, it is easy to see the big global differences inelectricity access. Comparing with the level of prosperity in the similiar countries,it is easy to see a connection. Level of prosperity increases with access to electric-ity. Knowledge and education is crucial when working with electricity. In manydeveloping countries, education is expensive and available only for the upper-classin the society. Thus, many remote areas still have no electricity. The most commonway of introducing electricity is by use of fossil fuel like a diesel generator. This isa cheap way to obtain electricity, but a costly way in long term, since fuel is ex-pensive. Fossil fuel is also a limited resource and should in a global perspective beavoided. Many articles are written about this topic the last decades, and the com-mon thread is that the global community has to tend towards a more sustainableway of managing the limited resources.
Using renewable energy sources instead of fossil fuel is an important step towardsthis goal. Energy sources like photovoltaic(PV)-, wind- and hydro power are allrenewable and with free supply of fuel. PV-energy is a much used energy source inmany remote areas. One of the reason is that the purchasing- and maintenance-costs are small. The charging- and control systems with batteries have become quiteadvanced compared to the cost. The last few years, small cheap wind turbines havebeen introduced to the global market. Compared with PV-energy, wind energy hashigher efficiency, but larger mechanical forces and stress are introduced. Thus,wear and maintenance costs increases. Hydro-energy is a stable energy source withhigh efficiency. It is depending on location and access to water. Building smallreservoirs increase the flexibility of this energy source.
Remote HydroLight is a full-range supplier of micro hydro power plants in Afghanistan.The company has been involved in training of personnell, manufacturing of com-ponents and installation of hydro power plants. Finding cheap, simple and robustsolutions for power plants in remote areas has been an objective for the company.
1
CHAPTER 1. INTRODUCTION
One of the tasks has been to develop an easy and cheap governing system with lowmaintenance costs. Using equipment locally produced in Afghanistan has reducedthe costs in the production a lot.
In this master thesis, a governing system (electronic load controller) producedby Remote HydroLight has been tested and connected to a cross flow turbinemanufactured by the same company. In addition, a proposal for connection betweenseveral energy sources in a stand-alone power system has been described.
The thesis is structured in chapters and headings in order to make it surveyableand easy-to-follow. It starts with a general introduction about the turbine, gen-erator and governing system. In the next chapter, the controller and the relationbetween the most important parameters used in the experiments are presented.In Instrumentation the equipment used in the experiments are described. Theprocedures for the tests are explained in Method. The most important resultsfrom the work are prestened in Results, and these are discussed in the Discussionchapter .In Further work several recommendations for further investigations areexplained. A summary of the results and discussion is presented in Conclusion. Inappendix, calibration data, data sheets from equipments used in the experiment,software used for logging of data and a HSE-repport for the work in laboratory areattached.
Figure 1.0.1: View of Earth from outer space at night
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Chapter 2
Background
2.1 Cross-flow turbine (Ossberger turbine)
The Cross-flow turbine is an impulse turbine where all pressure energy is convertedinto kinetic energy when entering the runner (ideal case). At the inlet of the turbinea large guide vane is located controlling the volume flow into the turbine. Therunner consists of a large number of vanes (up to 37) located symmetrically aroundthe runner. The water enters and flows through the turbine before exiting throughthe runner vanes on the other side of the turbine. The turbine can be splitted upin several chambers with runner vanes. This multi-cell turbine is better adaptedto varying volume flows, since the area of the inlet is adjusted in two directionsby valves. (see figure 2.1.1b) It is operating with a range in head of 2,5-200m anddischarge range of 0,04-13m3/s. The turbine is provided with a power range of 15-3000kW by the manufacturer. A mean efficiency of 80% is expected for small poweroutputs and higher efficiency (up to 86%) could be obtained for larger units. Sincemost micro hydro plants in developing countries have no reservoirs, the volumeflow during the year is changing. For these run-off plants, the multi-cell cross-flowturbine is a good choice. [9]
2.2 Generator
In the generator, the mechanical energy from the runner is transformed into electricenergy. Generators in small stand-alone powerplants generally belong to one of thefollowing categories: induction generator with a capacitor bank (IG) or permanentmagnet synchronous generator (PMSG). The simplest and also cheapest generatoris the IG. It is easy to control the voltage, but has limitations in speed variationand efficiency. The PMSG has better efficiency, but large cost and limited variationin speed are the major drawbacks. [7]
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CHAPTER 2. BACKGROUND
(a) Principle of a cross-flow turbine(b) Stable efficiency curve when using amulti-cell turbine
Figure 2.1.1: Cross-flow turbine
For micro hydrosystems below 30 kW , IG is the recommended solution. The IGis cheap and robust. To run it with overspeed does not damage it, and mainte-nance costs are small. It is also possible to run it on lower nominal speed, andthen get a lower transmission ratio. For systems with a capacity >30 kW , thesynchronous generator is a better solution, and this is also the solution used inRemote HydroLight’s projects in Afghanistan.[7]
2.3 Electronic load controller (ELC)
A well-developed power grid is in many countries non-existent. In many remoteareas, a stand-alone power system (SAPS) is the only feasible choice. The ELCis a much used governing system for these power systems. The controller keepsthe torque constant by connecting and disconnecting dump loads frequently as the
4
CHAPTER 2. BACKGROUND
consumption loads change. Thus, it works like an electronic brake on the generator.The dump load energy is in most projects used for heating water. It is a small andcheap solution for controlling the power output. For small run-off-river systemsit is a very preferable system, since the alternative is that the dump load energywould dissipate anyway.
The ELC that is tested in lab has a capacity of 6 kW and is manufactured byRemote HydroLight in Afghanistan. By the end of september 2012, 1750 ELC’shave been installed in Afghanistan by Remote HydroLight. The motivation for thecompany has been to develop a simple but robust controller with a quality thatis appropriate. The ELC is only possible to connect to a synchronous generator.Producing an ELC for connection with induction generator is planned in the future.
2.4 Earlier work
In 2008 a cross-flow turbine manufactured by Remote HydroLight (RHL) was in-stalled in the Waterpower Laboratory at NTNU. The turbine, also known as theIAM-turbine had a diameter of 270mm, width of 335mm and a power outputwithin 1-22 kW .
In 2008, an efficiency test was performed on the IAM-turbine in the Waterpowerlaboratory at NTNU by two master students: Eve Kathrin Walseth and SvenOlaf Danielsen. The laboratory is IEC approved and the IAM-turbine perfomedmax efficiency of 78.6 ± 0.9 % with 5m head and 80% nozzle opening. An CFD-simulation was performed to locate the losses in the inlet and through the runner.The simulation showed a great potential in design of both the inlet and runner.[21]
In 2009, Eve Cathrin Walseth continued working with the IAM-turbine. Furtherinvestigation of the flow through the runner was done. A visualisation of the flowby use of a single-lens camera and stroboscopes was carried out showing how thedirection of the flow changed by changing the nozzle opening. The torque transferwas also investigated by use of strain gages. The results showed that the turbineworks well for large nozzle openings. The flow enters the runner close to the nozzlethat results in an inlet angle that corresponds well with the angle of the blade.The investigation of the torque showed that 53,7 % of the torque was transferredthrough the second stage. [20]
In 2013 masterstudents Oblique Shrestha and Supriya Koirala continued workingwith the IAM-turbine. The efficiency was investigated and a rig with high speedcamera, lightning and mirrors was installed. This resulted in better visualisationof the flow through the runner. [12]
5
CHAPTER 2. BACKGROUND
6
Chapter 3
Theory
3.0.1 Direct Current (DC) and Alternating Current (AC)
In a DC-circuit the direction of current is constant. A standard nominal voltage forDC-circuit is 12V . This is the same voltage-level as used in standard automotivebatteries (lead acid batteries). For high power electric equipment using AC, aninverter is used to convert from DC to AC.
In an AC-circuit, the direction of current is constantly changing. The number ofoscillations per second is set by mains frequency (explained in the next section).Unlike DC, AC is well suited for transforming up to high voltage. For transportover large distances high voltage AC is the best solution to avoid large losses inthe grid. The national grid is a three phase AC-system. The electricity is thendistributed in three different phases and transported in four separate lines whereone is connected to ground. In Norway, the nominal voltage on the grid is 220Vinto the households.
3.0.2 Mains frequency
Frequency is defined as the number of cycles per unit time. The SI-unit for fre-quency is Hertz (Hz= 1
s ). Thus, 1 Hz is equal to 60 cycles per minute. Mainsfrequency (utility frequency) is defined as the frequency of oscillations from a sine-wave-formed AC-curve. From eq.3.0.1, the coherence with generator speed andnumber of pairs of poles is established. It is important that the frequency is con-stant. If there is a marked drop in frequency, sensitive electronic equipment may bedamaged. In Norway and in many western countries, 50Hz is the standard mainsfrequency. This is different from Canada and USA where 60Hz is standard. ForNorway, a variation of ± 0.1Hz is set as limit.
7
CHAPTER 3. THEORY
The connection between rotational speed,n, pairs of poles P , and mains frequency,fmains can be expressed:
fmains =n · P60
(3.0.1)
Figure 3.0.1: Principle of mains frequency
3.0.3 Electric Power
Electric power can generally be described as work done per unit time. Watt [W ]isunit, defined as J/s. Power is depending on current I,voltage U and phase angle θ.θ is defined as the angle between the current- and voltage-sine wave. The generalrelation in an AC circuit is:
P =1
2U · I · cosθ = URMS · IRMS · cosθ (3.0.2)
Figure 3.0.2: Power triangle
The power triangle displayed in figure 3.0.2 describes the relation between real-,reactive- and apparant power. When equipment with capacitors or coils are intro-duced in a circuit, a reactive contribution in power appears. For a pure resistivecircuit, reactive power is 0. Thus:
8
CHAPTER 3. THEORY
P = U · I = I2 ·R (3.0.3)
Since only resistive loads are connected in the experimental setup, the reactivecontribution is 0 and will not be considered further.
3.0.4 RMS-value
The root-mean-square-value (RMS-value) is a statistical parameter that is used tofind the magnitude of a signal. It is very useful when a signal is both positive andnegative, like the AC sine wave. The RMS-value for a continous function f(t) overa time interval T1 ≤ t ≤ T2 can generally be expressed:
fRMS =
√1
T2 − T1
∫ T2
T1
[f(t)]2 dt (3.0.4)
An AC voltage sine wave can be expressed:
V (t) = Vpsin(ωt) where Vp = peak voltage (3.0.5)
Using this equation, the RMS-value for the AC-voltage signal can be expressed:
VRMS =
√1
T2 − T1
∫ T2
T1
[Vpsin(ωt)]2 dt
= Vp
√1
T2 − T1
∫ T2
T1
[sin2(ωt)] dt
= Vp
√1
T2 − T1
∫ T2
T1
1− cos(2ωt)2
dt
= Vp
√1
T2 − T1
[t
2− sin2ωt
4ω
]T2
T1
Since it is a periodic signal the sine-part removes. Thus:
VRMS =VP√
2(3.0.6)
The RMS-value of an AC voltage signal can be described as the equivalent DCvoltage that would dissipate equal amount of heat. Similar analysis is used forfinding IRMS .
9
CHAPTER 3. THEORY
IRMS =IP√
2(3.0.7)
3.1 Test rig
3.1.1 Necessary parameters
In order to define an operating point for the cross flow turbine, it was necessary tomeasure the following parameters: discharge, pressure, rotational speed and watertemperature. This was done in order to make it easier to repeat the tests andvalidate the results. To control the electric power to the ELC, current and voltagewas measured.
3.1.2 Hydraulic power
Hydraulic power is defined as power derived from motion and pressure in a certainliquid. Hydraulic power in a hydro system is given by eq.3.1.8. This is not used inthe experiments, but explains the correlation between density, discharge and nethead.
Ph = ρ · g ·Q ·Hn · ηh (3.1.8)
Here the density is determined by measuring atmospheric pressure and water tem-perature [8]:
1
ρ= V0
[(1−A · p) + 8 · 10−6 · (θ −B + C · p)2 − 6 · 10−8 · (θ −B + C · p)3
](3.1.9)
V0 = 1 · 10−3m3/kg
A = 4, 6699 · 10−10
B = 4, 0
C = 2, 1318913 · 10−7
Note: p = pabs [Pa] and θ=temperature [C]
10
CHAPTER 3. THEORY
Acceleration of gravity
Norwegian Metrology Service (Justervesenet) has measured the acceleration ofgravity in the Waterpower laboratory:
g = 9.821465m/s2 (3.1.10)
Net head-Hn
The specific hydraulic energy (Net head Hn), was determined by using Bernoulli’sequation from inlet of the turbine to center of the turbine. The level difference wasmeasured between center of the pipe and center of the runner. The velocity at theinlet was set by measuring the discharge and using the diameter of the pipeline.
Hn =Pi
ρg+ Z +
v2i2g
(3.1.11)
Converted into pressure:
m = ρ · V (3.1.12)
F = m · g (3.1.13)
p = F/A (3.1.14)
1bar = 1 · 105Pa = 100kPa (3.1.15)
1Pa = 1 · 10−5bar (3.1.16)
Example: 5mWC at 20 C converted to bar:
m = 998, 2071kg/m3 · 5m3 = 4991, 0355kg
F = 4991, 0355kg · 9.821465m/s2 ≈ 49019N
p =49019N
1m2= 49019Pa = 0, 49019bar
Velocity at the inlet:
Q = Ai · Vi (3.1.17)
Vi =Q
Ai=
Q
π · (Di
2 )2(3.1.18)
11
CHAPTER 3. THEORY
Hydraulic efficiency
Hydraulic efficiency, ηh, is defined as the ratio between output mechanical powerand input hydraulic power. ηh is between 0 and 1 and is expressing the hydrauliclosses through the turbine. Mechanical power was not measured, but use of elec-trical power instead gives almost similiar results.
ηh =Pm
Ph(3.1.19)
12
CHAPTER 3. THEORY
3.2 Uncertainty analysis
Error is by the International Electrotechnical Commision (IEC) defined as the dif-ference between a measurement and the true value of the quantity. Uncertainty isdefined as the range of values likely to enclose the true value. A 95% confidenceinterval is a standard requirement, meaning the true value is expected with 95%probability to lie within this range. This is important information about the mea-surements and should always be included. Errors in experiment can be categorisedas spurious-, random- and systematic errors. [8]
3.2.1 Spurious errors
Errors detected from human failure or instrumental malfunction are examples ofspurious errors. If spurious errors are detected during the experiments, the resultsare not valid and should be discarded. Better preparations and clear proceduresare strategies for reducing these errors.
3.2.2 Random errors and related uncertainty
Random errors occur as small fluctuating differences in measurements. They aredeviating from the true mean value, according to the laws of chance. The randomuncertainty is depending on number of samples and operating conditions. Whenthe number of samples increases, the random uncertainty decreases. Keeping theoperating conditions constant is reducing the deviation from the mean value, lead-ing to a reduction in random uncertainty. To determine the random uncertainty inthe measurements, sample standard deviation s first needs to be calculated: [14]
s =
√∑Ni=1 (xi − x)2
N − 1(3.2.20)
xi= independent measurementx=arithmetic mean valueN= number of samples
The mean standard deviation of the mean value for a set of measurements is thendefined:
σm =s√N
(3.2.21)
Student’s t-factor is used to correct the random uncertainty for small number ofsamples. When a measurement has a large number of samples, a Gaussian (normal)
13
CHAPTER 3. THEORY
distribution is assumed to give an applicable representation. Absolute error e isthen determined:
e =t · s√n
=1.96s√N
(3.2.22)
For the experiment,t-distrubution was used due to a relative small number of mea-sured values. The relative random error fr (in %) can be calculated:
fr =e
x· 100 (3.2.23)
Systematic errors and related uncertainty
Systematic errors are expected in all measurements and are independent of numberof samples. They are internal errors that are constant, predictable and occuringduring the entire experiment if operating conditions remain constant. If the as-sumptions or operating conditions change during the experiment, it is likely toexpect that also the systematic error will change. To determine the systematicerror, two different measuring system have to be used, and the deviation in eachmeasurement has to be evaluated. It is also possible to evaluate the error by usingexperience and obtain a subjective estimate. Precise measuring equipment andgood accuracy in calibration of measuring equipment are important factors forreducing the systematic errors.
It is important to identify all contributors of systematic errors when evaluatingsystematic uncertainty. The total systematic uncertainty, fs,t, is defined by theRoot-Sum-Square (RSS)-equation consisting of all systematic uncertainties fromthe measured variables:
fs,t =√∑
fs,i2 (3.2.24)
Total uncertainty
The total uncertainty,ft, in a measurement is evaluated by using the RSS-relation.The total uncertainty includes contribution from both random and systematic un-certainty and is expressed in equation 3.2.25.
ft =
√fs,t
2 + fr2 (3.2.25)
14
CHAPTER 3. THEORY
3.2.3 Uncertainty analysis of experiments
During the experiments both generator- and dump load voltage were measuredfrequently with a data aquistion-module. The module was not calibrated beforethe experiment started, resulting in an accuracy in voltage signals of ±0.4% givenby the manufacturer. [10] Current and power were measured by a power analysinginstrument Voltech PM3000A, with an accuracy of ±0.5%. [11] There are notidentified other significant systematic contributors in the experiment.
Before and after every test was performed, random uncertainty in the measuredparameters was calculated. This was done to verify that the values and the perfor-mance were stable and did not affect the logging of dynamics when testing started.
15
CHAPTER 3. THEORY
3.3 Governing system - Electronic load controller
The Afghan company Remote HydroLight (RHL) has developed an electronic loadcontroller (ELC) for micro hydro power plants located in remote areas. The con-troller is a simplified version of Jan Portegijs’ ELC, the Humming Bird [15], mod-ified by Anders Austegard. The cost is important, and one of the main goals forthe company has been to develop a simple and understandable ELC that can beproduced in Afghanistan by the Afghan people. Even if it is simple, it has beenimportant to develop a robust controller with a quality that is appropriate. RemoteHydroLight’s ELC is tested for micro hydro power plants with capacities up to 45kW . It has also been installed on hydro power plants with larger capacities, butthen with several ELC’s connected in series. By the end of september 2012, 1750ELCs have been installed in Afghanistan. To decrease the cost and make it easyto handle, many simplifications have been implemented compared to the originalHumming bird. [5] A cost estimate for a 6kW three-phase controller with digitalcard is set up in appendix B.2.1.
The controller is developed for connection with a synchronous generator in a standalone power plant. It is connected to one or several dump loads that are triggeredby triacs in order to brake and regulate the turbine. Heating elements are used asdump loads and are either installed in a water-filled tank or in the river downstream.Often, more than half of the energy produced is consumed in dump loads. Thissounds quite ineffective, but for most of these micro hydro power systems storingwater in reservoirs is not an option. The intake is usually located in a river and thewater that is not used, is lost energy anyway. The cost of a speed control governorlike an oilhydraulic mechanical system is so high that in many cases it is moreeconomical to use an ELC with dump loads instead. In RHL’s projects, a watertank with several heating elements connected is used as dump load system. Theprinciple of the system is shown in figure 3.3.3.
Figure 3.3.3: Principle of electronic load controller
16
CHAPTER 3. THEORY
Phase angle regulation
The controller uses phase angle regulation to divert the power to the dump loads.The dump loads are triggered by triacs at a certain phase angle between 0 and180. This is referred to as the trigger angle. When the dump loads are triggered,they start conducting until the generator voltage crosses the 0V -line. This responseis continous and appears twice for each AC-period. (see figure 3.3.4).
Figure 3.3.4: Generator voltage with dump loads triggered at 70
Digital/Analog control systems
The control system of the ELC is located on the printed circuit board (PCB). RHLproduces both digital and analog PCBs to their control systems. The analog card(PCB) uses frequency as input for regulation. Analog cards are mainly recom-mended in projects where two generators are operating synchronously. Comparedwith a digital card it has a larger range in voltage, and may be used in systemswhere extra high or low voltage is required. One example is projects with largetransmission losses. Analog cards are frequently used in older versions of ELC, butare generally more complicated and more expensive to produce.
The digital card is controlling voltage. It is the most used solution for new ELCs,and is cheaper and easier to produce. [5] In the experiments, a digital three-phasecard is used. In the next sections only the digital version is described.
17
CHAPTER 3. THEORY
Response of a small reduction in consumption load
In most projects the consumption loads (village) are connected in parallel. Fromeq.3.3.26, a reduction in consumption load results in an increase of total resistance,RTot. Thus, from equation 3.3.27 and 3.3.28, a reduction in load leads to a reduc-tion in current and torque. Since power P is constant, angular velocity, ω, mainsfrequency n0 and the generator voltage, Ugen will increase. The load controllertriggers several dump loads simultaneously, in order to keep the torque and voltageconstant. A reduction in consumption load will lead to a smaller trigger angle andthus dump load voltage (RMS) will increase.
Response of a small increase in consumption load
In the opposite situation, a small increase in consumption load will lead to a de-crease in the total resistance. This results in an increase in torque and current.Power P is still constant and angular velocity, ω, mains frequency n0 and the gen-erator voltage, Ugen will decrease. The controller responds by varying the triggerangle of the dump loads in order to keep torque and power constant. An increasein the consumption load will result in a larger trigger angle and thus dump loadvoltage (RMS) will be reduced.
For a parallel connected consumption load:
1
RTot=
1
R1+
1
R2· · · (3.3.26)
P = U · I = R · I2 =U2
R(3.3.27)
PMechanical = T · ω (3.3.28)
n0 =60 · ngp
(3.3.29)
where: n0=mains frequency [Hz], ng=rotational speed generator [RPM] , p= num-ber of pairs of poles [-]
18
CHAPTER 3. THEORY
3.3.1 Critical situations
Overload situation
Generally, when several user loads are connected, current and torque increases.This leads to a drop in generator voltage. To counteract this, the trigger angle ofthe dump loads increases until torque and voltage is back to the set points. Whenconsumption load is equal to the capacity of the power plant, no load is divertedinto the dump loads. If more user loads are connected, an overload situation willoccur. The generator speed will decrease resulting in a new operational point forthe turbine and generator. Since best efficiency point (BEP) normally is set forthe turbine, this results in a reduction of power output. The response dependson the connected components. Generally, generator voltage will drop until a newstable operational point is reached. For an electrical fan this will reduce the speedof the fan. For a bulb this may result in flashing. Since the consumption loadnormally consists of several different components it is hard to predict the responsedirectly. In RHL’s projects, fuses are installed in each family house to reduceoverload situations and to detect where the overload occured. To reset the fusesthe family must contact an operator and this reduces later overvoltage situations.
Rapid off-load situation
If an error occurs on the transmission lines, the generator suddenly looses theconsumption load. This results in a reduction in current and torque. Thus, thegenerator voltage will increase. To withstand this, more power is diverted to thedump loads and the trigger angle is decreased. If some of the dump loads are dam-aged or disconnected, the generator speed and the generator voltage will increaseuntil a new stable operational point is obtained. If all dump loads are disconnected,a run-away situation occur. This is a critical situation where the turbine will spinup to run-away speed (where efficiency is 0) and equipment may be damaged.
19
CHAPTER 3. THEORY
3.3.2 Front panel of the ELC
A 6kW ELC, similar to the one used in the experiments, is shown in figure 3.3.5.
Figure 3.3.5: Electronic load controller developed and manufactured by RemoteHydroLight
Diodes
Four small light emitter diodes (LEDs) are installed on the left side of the frontpanel of the ELC. Their objective is to display the status of the ELC:
Red LED: Overvoltage situation, meaning that all power is directed to thedump loads.
Green LED: Voltage level in the village is normal and no power is divertedin the dump loads,
Red LED: Undervoltage situation. In this situation no power is directedto the dump loads and the frequency of the generator may bereduced.
Green LED: Voltage level in the village is normal and the dump load is partlytriggered.This means some of the power is directed to the dumploads.The brightness increases when trigger angle decreases.
Three larger LEDs (orange, red and green) are installed in the center of the frontpanel. When they light, they indicate that voltage is connected on each of thethree phases from the generator.
20
CHAPTER 3. THEORY
Meters
Two voltage meters are installed on the ELC that was evaluated. The first meterdisplays the generator voltage (RMS), and the other displays the voltage of thedump loads (RMS). It is also possible to install one or several amp-meters bymeasuring the current through the coil.
Fuses
Three fuses are installed between the ELC and the consumption load. They pro-tects the village from overvoltage and damage on electrical equipment. When thefuses blow, all energy is diverted in the dump loads.
Cabinet
The cabinet is protecting the different modules against overheating, water leakageand moisture. RHL suggests two different boxes: one low-cost and one more robust.The low-cost cabinet contains of a steel cover with openings on the sidewalls andat the bottom. The more robust alternative uses a larger cabinet with a door andopening on bottom. On top of the cabinet it is a small gap for ventilation.
Dump load system
The dump load system consists of several resistive heating elements where excessenergy from the village is used to heat water. In RHL’s projects, a steel tankis used with heating elements installed at the bottom of the tank. Installing theelements at the bottom is done to avoid dry-out and give better circulation sincehot water will rise. This kind of solution is shown in figure 3.3.6
Figure 3.3.6: Water heater used in RHL’s projects
21
CHAPTER 3. THEORY
3.3.3 Inside the ELC
In figure 3.3.7 the components inside the ELC is displayed. In the next sectionsthe different components are described briefly. The circuit diagram for the ELCused in the experiments is given in appendix B.2.
Figure 3.3.7: Inside the electronic load controller
3.3.4 Signal distribution
Generator voltage (220V AC) is used as input to the ELC. The signal is connectedto the village only separated by fuses. The signal is also directed to the varistorand transformer that makes the entrance of the ELC.
22
CHAPTER 3. THEORY
Varistor and transformer
A 220V/6V transformer is used before the signal enters the card. This is becausethe components on the card are not able to handle such high voltage. To avoidhigh peaks in the voltage signal, a varistor is installed in front of the transformer.The varistor works like a simple overvoltage protection by avoiding damage on thecard and the transformer.
Digital card
The digital card (PCB) used in the tests is shown in figure 3.3.8. Centrally locatedon the PCB is the microcontroller. RHL uses a Texas Instrument MSP430F2012microcontroller in their design. The controller has an A/D converter with a sam-pling rate of 12600 samples per second for each phase. It has 14 terminals, 128byte RAM memory and 2kB flash memory.[5]. Since both input and output of thecard is connected to phases (see circuit diagram in appendix B.2), thermistors areused on the output to the triacs to prevent high voltage to enter the PCB.
Figure 3.3.8: Digital 3-phase PCB used in the experiment
23
CHAPTER 3. THEORY
Governing parameters
The accumulated mean value of the generator is used as input signal for the gov-erning parameters. This value is used instead of the RMS-value, due to stabil-ity. To govern the system, the controller uses a Propotional-Integal-regulator (PI-regulator).The proportional part is based on frequency and the integrator-part isbased on voltage. The governing parameters have been tuned by Remote Hydro-Light. They are conservative chosen to avoid unstable situations and equal for allof the ELCs that RHL has installed in Afghanistan. The generator voltage level(RMS) is set to 230V ± 5V . For small corrections in setpoint of voltage, a varistorlocated on the PCB is utilised.
Triac and coil
The triacs are used to trigger and divert power to the dump loads. The triacsconduct in both directions and each dump load is connected to one triac. RHLuses original triacs from ST Microelectronics (BTA40-600B). These componentshave capacity up to 40A and 600V. This results in less problems with overloadand makes the ELC more robust.To protect the triacs, ferrite coils are used andconnected in series with the triacs.
The triacs are triggered in a single step process, meaning that all the triacs triggerin the same moment. This results in a rapid response in the generator voltage andmay lead to noise and vibration.
Heat sink
During operation the ELC produces a lot of heat. To avoid damage on sensitiveelectronic components, it is necessary to cool down the controller with air. Thecontroller uses heat sinks of aluminum with several fins to increase the surface area.Each heat sink can be connected with two triacs. The heat sinks are located onthe outside of the ELC in order to get proper ventilation.
3.3.5 Experience from RHL’s projects
Anders Austegard and Remote HydroLight started with production of analog ELCsin 2006. In 2009 the digital ELC was released. Compared with the analog version itwas a much more reliable solution and easier to construct. Poor component qualityhas been a common thread on the problems that has occured since the beginningof production.[5] [3]
One of the major problems has been brakedown of heating elements. Poor qualityheating elements from China has led to fatigue and failure on several elements. Highquality heating elements are much more expensive than elements from China, but
24
CHAPTER 3. THEORY
in many projects the people in the village do not want to spend extra money on this.Finding high quality original parts has generally been a challenge. In some cases,non-original triacs and transformer have been installed by other companies and thishas resulted in failure. In most of RHL’s projects the generators are manufacturedin China. To increase the durability, many of the electronic components are changedwith higher quality parts before installation on the plant.
There have been some problems with water leakage and moisture on the connectionsbetween the heating elements and the wire. Condensation has resulted in moistureon the connections between the terminal on the heating element and the wire.Thus, short circuit and failure has occured.
In RHLs first projects, the triacs were connected in parallel. This led to a moreharmonic generator voltage curve, due to less influence of the triacs. However, thecircuit also became more complicated and in later projects the triacs have beenconnected in series instead.
In general, the digital ELCs seem to work much better than the analog ELCs. Theuse of thermistors at the outlet of the PCBs have been an important factor, butalso improved simplicity and robustness of the system.
25
CHAPTER 3. THEORY
3.4 Improvements of the ELC
Phase angle regulation with triacs is a simple way of controlling an energy system.It is a cheap and robust solution, but with limited range of application, since onlyresistive dump loads can be connected. The quality of the signal is poor. Each timethe triacs trigger, a rapid peak in the generator voltage occur. This disturbancemay create problems when connecting and synchronising with other energy sources.Jan Portegijs mentions two different alternatives to phase angle regulation: PulseWidth Modulation (PWM) and Binary Loads (BL). [15]
3.4.1 Pulse width modulation
Pulse width modulation (PWM) is a commonly used technique for modulating avoltage signal. PWM uses modern transistors like IGBT or MOSFET to set up apulse signal. In general the signal in PWM is either on or off. The method uses thewidth of the pulse signal to determine the average voltage signal (see figure 3.4.9).The time the signal is on (the width) is defined as the duty cycle. By varyingthe duty cycle, the output voltage signal is changed. Since the voltage level isproportional to the power, it will in an ELC-circuit be controlling the power to thedump loads.
Example: When the consumption load decreases, the generator voltage level in-creases. In order to keep a constant voltage level, power has to be diverted to thedump loads. This is achieved by increasing the duty cycle of the signal. Thusthe average voltage signal increases and the power diverted to the dump loads in-creases. The frequency of the PWM-signal has to be set larger than the change ofthe system to provide stability. It is also important to make it different from theaudible frequency range to evade noise.
In general, PWM has an advantage with a simple electronic circuit to controlmodern power transistors like IGBT and MOSFET. Disadvantages include highprice, poor availability and sensitivity of the power transistors. [15]
3.4.2 Binary loads
The second alternative, binary loads (BL), uses a set of dump loads where thecapacity of the second load is half of the first load. This gives 2n combinationsfor the dump load system. To trigger these loads, Solid State relays are used. Byuse of BL there is no problem with electric noise due to triggering only at thebeginning of each half period, or no triggering at all. However, there are also somedisadvantages; The costs of the relays are rather high compared with triacs, and alarge number of dump loads are required. [15]
26
CHAPTER 3. THEORY
Figure 3.4.9: Principle of PWM [13]
Figure 3.4.10: Principle of binary loads [15]
27
CHAPTER 3. THEORY
3.5 Hybrid energy systems
Since the energy demand and energy availability is changing through the year, itis often necessary to introduce several energy sources. A hybrid energy systemconsists of two or more energy sources resulting in increased power supply andpower balance. In the next sections wind energy, photovoltaic energy and energyfrom fossil fuel are explained.
3.5.1 Photovoltaic energy
Photovoltaic (PV) energy is a widely used source for energy production. Photovoltaic-cells are used to convert the energy from the radiation of the sun to electric energy.PV-energy generates DC-voltage, and to store the energy, several lithium-batteriesare connected in parallel. PV-cells have quite low efficiency compared with otherenergy sources. The efficiency for simple PV-cells is about 4-8 % (a-Si cells), but abit higher for more sophisticated cells (10-17%) [6] Because of mass production andlow prices, it is often the definite best and cheapest solution for bringing electricityto isolated households and villages.
3.5.2 Wind energy
Wind energy is a renewable energy source where kinetic energy in wind is convertedinto mechanical energy through a turbine. The turbine is connected to a generator.The last few years, small, cheap wind turbine systems have been introduced onthe global market. Compared with PV-energy, wind energy has higher efficiencyand generates both day and night. Major drawbacks are introduction of largemechanical forces and stress. Thus, wear and maintenance costs increases.
3.5.3 Energy from fossil fuel
Fossil fuel generators are much used in countries and areas with shortage of elec-tricity and energy resources. It consists of a diesel/gasoline engine and an electricgenerator. The advantages with fossil fuel generators are the flexibility and thesecurity of supply. The major disadvantages are large emissions, not renewablefuel and high cost. Since fossil fuel is not a renewable energy source, it should in aclimate perspective be avoided. High prices of fuel will in the long term result ina very expensive solution. Thus, the suggestion is to minimize the consumption ofenergy from fossil fuel.
28
CHAPTER 3. THEORY
3.5.4 Maximum power point tracking
Maximum power point tracking (MPPT) is a commonly used electronic system forobtaining maximum power in a variable energy source like a PV-module or a windturbine. During the day, the irradiation and wind intensity change. As a resultof this, the maximum power output changes. In order to achieve maximum powerfrom a PV-module, the best combination of current and voltage has to be chosen.For a wind turbine it is important to find the optimum rotational speed of theturbine (see figure 3.5.12 and 3.5.11). There are different versions of MPPT, fromsimple to more sophisticated methods. There are generally two main methods thatare used: Perturbation and Observation (P&O) and Model based control. Thefirst method uses input data to investigate if there is a positive or negative slope inthe power output. If the slope is positive, power output is increased and oppositeif slope is negative. Model based control, on the other hand, uses predeterminedequations for power output curves to quickly determine the optimal conditions.[16]
Figure 3.5.11: MPPT
Figure 3.5.12: Wind power plot
29
CHAPTER 3. THEORY
3.5.5 Inverter, rectifier and DC/DC-converter
Inverters and rectifiers are power electronic converters that convert between directcurrent (DC) and alternating current (AC). In order to vary the amplitude of aDC-signal, a DC/DC-converter is used. Pulse width modulation (PWM) can beutilised for this purpose. [2]
3.5.6 Energy management system
Connecting several energy sources results in a more complex energy system. Toachieve optimum performance of the system, a well functioning energy managementsystem (EMS) is required. The EMS has the overall control of the different energysources, and can change the performance of the separate modules directly. Thesystem may also control the energy access for the different user loads. A rankingsystem can be established to ensure reliability of supply for important loads. Afew examples may explain this better: If the battery is fully charged, the EMSmust reduce the energy production. If the energy demand is larger than the energyavailability, it is necessary to stop energy access to lower ranked loads like heatingof water and ensure energy to higher ranked loads, like a ward or a hospital. [2]
3.6 Hybrid energy system for remote areas
In many projects it is convenient to connect several energy sources together inorder to obtain a reliable and stable energy system. A hybrid energy system hasmany advantages. If one energy source fails, there is always a backup-system. Infigure 3.6.13, a hybrid energy system with a hydro power plant, a wind turbineand a PV-module charging a battery bank is displayed. In this system, a parallelDC-grid with a voltage-level of 300-400V is used. The hydro power plant is directlyconnected with a rectifier. For the wind turbine, a rectifier and a DC/DC-converterwith MPPT are used to achieve the optimum rotational speed of the turbine. ThePV-module is connected to a DC/DC-converter with MPPT to attain maximumpower output.
A charging control system is connected to the battery bank. The control systemconsists of a two-way DC/DC-converter which makes it possible to both chargeand discharge, and for determining the optimum charging voltage. A dump loadsystem is used as backup in case of a failure in the EMS or in the charging system.For emergency situations and to handle top loads, a standby diesel generator isused. By increasing the battery bank and using a sophisticated energy managementsystem, the dependence of the standby generator is reduced.
The distance from the power plant to the village is important when consideringusing DC or AC. If it is long distance between the connected units and the con-sumers, it is suggested to transform up to high voltage (to reduce losses), and then
30
CHAPTER 3. THEORY
Figure 3.6.13: Hybrid energy system for remote areas
AC is the best choice. If the energy system is located close to the consumers, aDC-grid is a good choice. [2]
3.7 Hybrid energy system with ELC
For connecting a hydropower plant w/ELC to a PV-module, it is possible to usea simple rectifier and connect the two energy sources to a battery bank. Thissolution is illustrated in figure 3.7.14. The PV-module consists of a MPPT-systemand a DC/DC-converter in order to obtain maximum power output and the correctvoltage (300-400V ). When the battery bank is fully charged, the PV-module isdisconnected. With this solution, it is possible to use the existing ELC (with triacs)and only divert energy to the dump loads when the battery bank is fully chargedor a failure has occured. An energy management system can be implemented forbetter control and better utilising the different energy sources. This is not requiredfor the system, but will increase the quality and efficiency of the energy system.This is specially recommended for larger and more complex energy systems wherea small increase in efficiency will result in a larger difference.
31
CHAPTER 3. THEORY
Figure 3.7.14: Stand alone hybrid energy system with ELC
32
Chapter 4
Instrumentation
4.1 Experimental setup
The piping network used in the experiment is shown in figure 4.1.1. Water waspumped up to the pressure tank where it stabilised and 5mWc head was set.Water was then directed into the cross-flow turbine. This setup is different fromWalseth/Danielsen and Korala/Shrestra’s setup that pumped water to the upperfree surface reservoir using a throttling valve to reduce the head. These setups mayhave introduced some cavitation just after the throttling valve and this may haveaffected the volume flow measurement. [4] To reduce this disturbance, the pressuretank was used instead and the correct net head, Hn, was obtained by changing therotational speed of the pump.
In figure 4.1.2, the principles of the governing system is shown. The generator wasconnected to the turbine via a belt drive. The generator was connected to the ELCand further to the consumption load. The signal from the generator was processedby the ELC and the remaining power was diverted into the dump loads. In thissetup, both dump loads and consumption loads were heating elements submergedin the lower reservoir in the laboratory.
33
CHAPTER 4. INSTRUMENTATION
Figure 4.1.1: Piping network for cross-flow turbine
Figure 4.1.2: Principle of experimental setup
34
CHAPTER 4. INSTRUMENTATION
Figure 4.1.3: Overview of the experimental test rig
35
CHAPTER 4. INSTRUMENTATION
4.1.1 IAM-turbine
The installed cross flow turbine was manufactured by Remote HydroLight (RHL)in Afghanistan. The turbine was a Traditional Mill Turbine (TMT) and was origi-nally designed by Owen Schumacher (RHL). After installation and testing in 2008by Danielsen and Walseth, the turbine was referred to as the IAM-turbine. Theturbine had a diameter of 270mm, a rotor width of 335mm and a tested poweroutput within 0-23kW .[21] It is estimated that more than 4000 turbines has beeninstalled with this design in Afghanistan. [17]
4.1.2 Generator
To convert the mechanical energy to electrical energy, a synchronous generator wasused. The generator was a Sincro GS4 LES imported by BEVI Sweden. It was anAC-generator with an apparent power of 25 kVA, a power factor of 0.8 and thus acapacity of 20kW . It consisted of brushes and had 2 pairs of poles resulting in anominal rotational speed of 1500 RPM . Datasheet for the generator is attachedin appendix B.1.
Since the turbine and generator had different speeds, a belt drive system wasinstalled, connecting the turbine shaft and the generator shaft. Gummi og maskin-teknikk AS designed the system resulting in a configuration with two V-belts. Theratio between turbine and generator speed was 1:3.57.
Figure 4.1.4: IAM-turbine and synchronous generator with belt drive (behind blackcover)
36
CHAPTER 4. INSTRUMENTATION
4.1.3 Electronic load controller
In order to control the power from the generator, an electronic load controller wasinstalled. The ELC was manufactured by RHL and was a simplified version of JanPortegijs’ ’Humming Bird’. [15] The structure of the ELC is described in section3.3.
The ELC used in the experiments had a capacity of 6kW . It was a three-phasedigital version where voltage from the generator was regulated and controlled. Thetest object had not been installed in any projects earlier. Three dump loads, eachwith capacity of 2kW , were installed. Each dump load was connected to one triacand two heat sinks were used to avoid overheating.
Due to Health, safe and environmental (HSE) requirements from the University(NTNU), all unoriginal non-western components had to be replaced with originalparts. Wires were changed, and all components and wiring had to be installed ina new approved terminal box. This was done in order to avoid damage in the lab.The transformer, the PCB-card, the triacs and the two heat sinks were approvedand were used in the new setup. The circuit diagram for the ELC is attached inappendix B.2. The HSE-repport is attached in appendix E.
(a) Inside (b) Outside
Figure 4.1.5: Electronic load controller used in experiments
4.1.4 Dump load system
The dump load system consisted of three heating elements with capacity of 2kWeach. The elements were manufactured by Norske Backer AS. Datasheets for theheating elements are given in appendix B.3. The elements were installed inside
37
CHAPTER 4. INSTRUMENTATION
pipes in a waterproof environment and submerged into the lower reservoir. Thepipes were connected with a beam perpendicular to the channel. The beam wasthen tightened into two girdeers parallel with the channel. See figure 4.1.6 fordetails around installation.
(a) Heating element(b) One of the seven heating elements sub-merged into the lower reservoir
Figure 4.1.6: Dump load and consumption load system
4.1.5 Consumption load system
In order to set up a variable consumption load, three heating elements with capacityof 2 kW each were used. Each of the heating elements were connected with a switchto one phase. To simulate an overload situation, an extra heating element of 1kWwas connected. The setup of the heating elements were similiar to the dump loadsystem and the heating elements were submerged on the same beam perpendicularto the channel.
38
CHAPTER 4. INSTRUMENTATION
4.2 Measurements
Since the capacity of the ELC was much smaller than the turbine/generator, it wasimportant to control hydraulic and electric power to avoid overload. To determinethe hydraulic power, pressure, discharge and water temperature were measured.Electric power was measured with a power analyzing instrument.The instrumentsused in the experiment are given in table 4.2.1.
Measurement InstrumentPressure Fuji Electric France SAFKKW37V1AKCYYAEDischarge Krohne Aquaflux F6Rotational speed turbine Jaquet AGWater temperature Systemteknikk AB S1220Temperature ELC PT-100Electric power Voltech PM3000AData acquisition hydraulic power NI PCI-MIO-16XE-10Data acquisition ELC NI 9225
Table 4.2.1: Instruments used in the experiments
4.2.1 Logging instrument - IAM-turbine
A data acquisition(DAQ)-unit from National Instruments was used for logginghydraulig performance on the IAM-turbine. The unit had 16 input channels, maxsample rate of 1.25 kS/s and a range of -10 – 10V. To analyse and convert rawdatato values with comprehensible units, a program in NI LabVIEW was established.See appendix C.1 and program given in electronic version for details about theprogram.
4.2.2 Inlet pressure
Four pressure taps were installed at the pipeline and connected to a pressure trans-ducer. The pressure taps were evenly distributed perpendicular to the flow up-stream the turbine. The pressure transducer consisted of a high and low pressureside, divided by a membrane. The inlet pressure was connected to the high pres-sure side and air to the low pressure side. The transducer measured the changein expandation of the membrane as a voltage signal. The pressure transducer wasmanufactured by Fuji Electric France S.A with a range of -2000kPa - 2000kPa.
4.2.3 Discharge
A Krohne flow rate meter (see figure 4.2.8) was used for measuring discharge. Theprinciple of the flow meter was based on Faraday’s law of induction. An electro-
39
CHAPTER 4. INSTRUMENTATION
Figure 4.2.7: Pressure transducer
magnetic field was introduced perpendicular to the flow. The flow of water workedlike a conductor in this field, resulting in an induced voltage signal. Since thecross-section was constant and the voltage signal was proportional to the velocity,it was possible to determine the discharge.
Figure 4.2.8: Krohne flowmeter
4.2.4 Rotational speed
Rotational speed of the turbine was measured optically using a photoelectric detec-tor and a reflector. The time between each reflection was measured and rotationalspeed determined.
Figure 4.2.9: Optical measurement of rotational speed on turbine
40
CHAPTER 4. INSTRUMENTATION
4.2.5 Water temperature
For temperature measurements at the inlet, a sensor manufactured by SystemteknikAB was used. A voltage signal was generated by the temperature difference betweenthe sensor and the water pipe.
Figure 4.2.10: Temperature measurements
4.2.6 Temperature - ELC
During operation the temperature inside the ELC-cabinet was measured with astandard PT100 resistive themometer. This was done to detect and avoid over-heating of the electronic components.
4.3 Generator- and dump load system
4.3.1 Logging instruments
A DAQ-module for high voltage signals (NI 9225) was used for logging generator-and dump load voltage. The unit had three input channels, sample rate of 50kS/s and a range of -300 – 300V. The logging program was established in NILabVIEW. From the program, the voltage signals were used to determine therespectively RMS-values, the frequency and the trigger angle. The LabVIEW-program is attached in Appendix C.1 and in electronic version.
4.3.2 Measurements
The generator voltage (phase to neutral) was continously measured with the DAQ-module. The signal was displayed in the LabView-program, and from this signalthe frequency and the RMS-value was evaluated. Dump load voltage (element toneutral) was also measured and from this signal the trigger angle and the RMS-value was determined.
Power output from generator was measured with a power analyzing instrument(Voltech PM3000A). Voltage and current were used as input parameters. Voltage
41
CHAPTER 4. INSTRUMENTATION
was directly connected and for current, three amp clamps were connected to theconductors from the generator. From the display of the instrument, power outputwas registered. The instrument was connected to the LabView-program and poweroutput (real power) and current were logged frequently.
42
Chapter 5
Method
5.1 Calibration
To obtain reliable results all measuring devices must be calibrated frequently. Thisreduces the uncertainty and validates the results. All calibrations were done ac-cording to the IEC 60193 standard. [8]. Before starting the experiment the volu-metric flow meter and the pressure transducer were calibrated. Details from thecalibrations can be found in appendix A.
5.1.1 Inlet pressure
The pressure transducer was calibrated with a portable pressure calibration gauge(Druck DPI 601). A static pressure was set up by the calibrator at the highpressure side, and air connected to the low pressure side of the transducer. Thepressure difference led to an expansion in the membrane that was measured as avoltage signal. Measuring pressure with pressure transducer is by IEC defined as asecondary measurement method. Calibrating against a portable pressure calibratoris not a primary measuring method, but it is a quick way to reduce the uncertaintyinto an acceptable level.
5.1.2 Discharge
The electromagnetic flow meter is defined as a secondary measuring instrument. [8]To obtain an approved calibration it was necessary to calibrate it against a primarymeasuring method. In the Waterpower Laboratory the weighing method is usedby measuring weight and time of filling of an approved tank. This is a primarymethod that is recommended according to IEC 60193.
43
CHAPTER 5. METHOD
(a) Pressure taps (b) Calibrator-Digital pressure indicator
Figure 5.1.1: Equipment for calibrating pressure transducer
The flow meter is calibrated by use of the weighing tank which rests on threeweighing sensors. These weighing sensors were calibrated by Andrea Stranna [19]in 2012. To calibrate the flow meter, the piping system had to be rebuilt. A tiltingscreen was used to direct the water either to the weighing tank or directly to thelower reservoir. The flowmeter was calibrated by leading water into the weighingtank for a certain time interval. The mass of the water and the time interval wasthen measured and the flow determined. Flow increased by increasing the pumpspeed and the valve opening. In order to fill the tank with minimum 2000kg eachinterval, the time varied between 30 and 70 seconds,.
Figure 5.1.2: Rebuilding the piping system for calibration of flow meter
44
CHAPTER 5. METHOD
5.2 Procedure for experiments
Several stress tests were accomplished to investigate the performance of the gov-ernor. Such tests are recommended to do before installing a new ELC in order toverify the quality of the system and avoid damages.[15] Before all tests (except thepower test) started, random uncertainty in logged parameters was calculated. Thiswas repeated when the tests finished in order to validate the results in the differenttests.
5.2.1 Power test
To test the reliability of the controller and the experimental test rig, the rig wasrunning on different loads and with different inlet pressure. The aim of this wasto detect overheating in the components and wirings inside the ELC and to de-tect weaknesses in the installed equipment. When stable operating conditions wasachieved, logging of four different load situations (0-4kW ) was performed.
5.2.2 Rapid on-load situation
During startup of the generator, the village is (usually) disconnected the plant inorder to prevent failure on electrical equipment. When the village is connecting tothe power plant, a rapid on-load situation occur. If the governing parameters arenot correctly tuned, an unstable situation may appear. The response in generatorvoltage (RMS-value), frequency, dump load voltage (RMS-value) and trigger anglewas logged during this situation.
5.2.3 Rapid off-load situation
A rapid off-load situation occurs if there is an error in the transmission lines tothe village. The consumption loads are then rapidly disconnected and all power isdiverted to the dump loads. Generator voltage, dump load voltage (RMS-values),frequency, and trigger angle were registered during the test.
5.2.4 Overload signal/undervoltage
To simulate an overload situation, an extra consumption load was connected. Theconsumption load was increased gradually until the ELC was overloaded. If thissituation occurs in a village, sensitive user loads may be damaged.
45
CHAPTER 5. METHOD
5.2.5 Run-away test
If the load on the generator is disconnected rapidly, the generator- and turbinespeed increases suddenly. It will increase until a stable speed is obtained. Thisis known as the run-away speed. The turbine and generator should be designedto withstand the mechanical forces that occur during this situation. Thus, it is agood way of checking the quality of the mechanical components. The load to thegenerator was disconnected by blowing the three fuses F1 at the input of the ELC.Rotational speed was measured during this test.
46
Chapter 6
Results
An experimental setup with a cross-flow turbine connected to an electronic loadcontroller (ELC) has been installed and tested in the Waterpower Laboratory atNTNU, September 2013. The intention of the experimental setup has been tosimulate a stand alone power system disconnected the national grid. The cross-flow turbine was a TMT-turbine manufactured by Remote HydroLight (RHL). Asynchronous generator was connected to the turbine. To obtain a nominal gen-erator speed of 1500RPM , a transmission system with belt drive (two belts) wasinstalled. The capacity of the ELC was 6kW and it was produced and developed inAfghanistan by RHL. The controller used phase angle regulation, a digital printedcircuit board (PCB) and three triacs to govern the power system. Due to HSE-requirements from the university (NTNU), the controller had to be rebuilt beforetesting could start. Wires, fuses and connectors were replaced, and all componentswere installed in a new approved cabinet. This increased the quality of the con-troller and reduced the risk of overheating and failure. Three heating elements withtotal capacity of 6kW were used as dump loads. To simulate a small village, 6kWconsumption loads were connected. Similar to the dump load system, three 2kWheating elements were used in the consumption load system. In addition, a 1kWheating element was connected in order to carry out an overload test of the system.The heating elements were installed in a waterproof environment, and submergedin the lower reservoir in the laboratory. The final test rig is shown in figure 6.0.1.
The performance of the controller has been evaluated with respect to step re-sponse in generator voltage and frequency. A power analysing instrument, VoltechPM3000A, was used for measuring electric power, and voltage was logged witha data acquisition module, NI 9225. The hydraulic perfomance of the test rigwas evaluated by measuring inlet pressure, discharge, water temperature and ro-tational speed of the turbine. The software for the experiment was programmedin NI LabVIEW, a graphical programming platform. Two separate programs wereestablished, one measuring hydraulic perfomance of the Cross flow turbine and an-other for logging electric performance of generator and dump loads. Both programs
47
CHAPTER 6. RESULTS
Figure 6.0.1: Final test rig
are attached in appendix C.1. Hydraulic and electric parameters for the differenttests are attached in appendix D.
6.1 Performance of the experimental test rig
The cross-flow turbine and the synchronous generator worked well during the ex-periment. The weak component in the rig was the transmission system. During thepower test, the belt drive started to slip, resulting in noise, high temperature andsmell of burning rubber. The belt drive was tightened, but the problem was stillpersistent when increasing the pressure and the generator speed. Due to shortanceof time, it was decided to use the existing belt drive system and reduce the poweroutput from the generator from 6kW to 4kW . The dump load capacity was keptat 6kW in order to avoid unequal distribution on the three phases.
Before the tests started and when the tests had finished, an operating point with6kW dump loads and 0kW consumption load was set and hydraulic parametersregistered. During the different tests, the pump speed and nozzle opening werekept constant. Approximately constant hydraulic performance on the test rig wasexpected, but during the testing the rotational speed of the turbine increased with2,33%. The parameters used in the operating point are shown in table 6.1.1.
48
CHAPTER 6. RESULTS
Start of testing End of testingHydraulic performancePump speed RPM 368,0 368,0Nozzle opening % 80 80Pressure kPa 49,034 ± 0,013 48,859 ± 0,013Turbine speed RPM 474,140 ± 0,081 485,20 ± 0,11Discharge m3/s 0,152541 ± 0,000016 0,1523614 ± 0,0000079Hydraulic power W 8380,4 ± 2,5 8342,0 ± 1,9Net head mWc 5,5980 ± 0,0014 5,5791 ± 0,0013Temperature C 14,603066 ± 0,000086 14,76722 ± 0,00020Density kg/m3 999,237387 ± 0,000014 999,212596 ± 0,000031
Table 6.1.1: Parameters in operating point
6.2 Performance of the ELC
6.2.1 Power test
During the first start-up tests of the rig, a failure in the connection of the triacswas observed. One of the triacs had been connected wrong and high voltage fromthe generator had been directed into the PCB from the outlet to one of the triacs.Fortunately the thermistors prevented the PCB from being damaged.
The ELC was tested with different consumption- and dump loads in order to detectweaknesses and limitations in the system. Four small LEDs (red and green) wereinstalled inside the ELC-cabinet to monitor status of the controller. A thermalsensor was installed between the heat sinks and the digital card. The generatorvoltage signal was measured from one phase to neutral and the dump load voltagesignal for one heating element was measured from heating element to phase. Asnapshot of the two voltage signals are displayed in figure 6.2.2 where 1kW con-sumption load is connected. The figure illustrates the rapid single-step triggeringresponse from the triacs. The abrupt triggering is affecting the generator volt-age signal with rapid peaks each half periode. Logging of the trigger angle waschallenging. A peak detector was used for identifying the peaks in the generatorand the dump load signal. Challenges regarding logging the first peaks and noisefrom the triggering of the triacs resulted in many outliers in the measurements.The ELC performed well during the testing. The temperature inside the cabinetincreased slightly during the testing, but no overheating or failure occured.
Important electric- and hydraulic parameters for different load situations are givenin table 6.2.2.
49
CHAPTER 6. RESULTS
Figure 6.2.2: Generator and dump load voltage. In this situation 6kW dump loadsand 1kW consumption loads are connected. The resulting trigger angle is 113
.
0kW 1kW 2kW 3kW 4kWGeneratorFrequency Hz 51,167 ± 0,010 51,149 ± 0,013 51,207 ± 0,016 51,3903 ± 0,0090 51,1139 ± 0,0089Voltage (RMS) V 230,42 ± 0,24 231,04 ± 0,24 230,33 ± 0,23 229,54 ± 0,23 233,47 ± 0,27Current (RMS) A 7,1544 ± 0,0011 7,32100 ± 0,00096 7,22265 ± 0,00083 6,88715 ± 0,00081 6,2100 ± 0,0011Apparent power (one phase) VA 1648,52 ± 1,79 1691,4 ± 1,8 1663,6 ± 1,7 1580,9 ± 1,6 1449,82 ± 1,67Real power (sum) W 4050,0 ± 1,2 4068,78 ± 0,72 4093,297 ± 0,499 4096,95 ± 0,38 4127,17 ± 0,43
Dump loadVoltage (RMS) V 193,37 ± 0,33 166,86 ± 0,34 138,62 ± 0,42 104,39 ± 0,31 48,10 ± 0,31Trigger angle deg 90,4670 ± 0,0096 112,96 ± 0,20 117,94 ± 0,17 122,38 ± 0,18 141,12 ± 0,82
Hydraulic performanceInlet pressure kPa 49,034 ± 0,013 48,962 ± 0,014 49,013 ± 0,014 48,958 ± 0,016 48,952 ± 0,012Turbine speed RPM 474,140 ± 0,081 474,571 ± 0,089 475,910 ± 0,088 478,14 ± 0,11 476,229 ± 0,088Discharge m3/s 0,152541 ± 0,000016 0,152490 ± 0,000017 0,152487 ± 0,000011 0,152483 ± 0,000013 0,1524171 ± 0,0000094Hydraulic power W 8380,4 ± 2,5 8366,1 ± 3,0 8373,6 ± 2,4 8365,1 ± 2,8 8359,8 ± 2,1Net head mWC 5,5980 ± 0,0014 5,5903 ± 0,0015 5,5954 ± 0,0015 5,5899 ± 0,0017 5,5888 ± 0,0012
Table 6.2.2: Power test - Different load situations
50
CHAPTER 6. RESULTS
6.2.2 Rapid on-load situation
A rapid-on-load situation was performed with an abrupt connection of 4kW con-sumption load (starting from 0kW ). This resulted in a marked step response ingenerator voltage (RMS) and frequency, displayed in figure 6.2.3 and 6.2.4. Impor-tant electric and hydraulic parameters are given in table 6.2.3.
Figure 6.2.3: Step response in generator voltage (RMS)
Figure 6.2.4: Step response in frequency
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CHAPTER 6. RESULTS
Stable operating point - 0kW Stable operating point - 4kW Stable operating point - 0kWGeneratorFrequency Hz 51,145 ± 0,010 51,1205 ± 0,0058 51,142 ± 0,010Voltage (RMS) V 230,16 ± 0,21 233,60 ± 0,19 230,15 ± 0,18Current (RMS ) A 7,06716 ± 0,00074 5,7901 ± 0,0054 6,8733 ± 0,0023Apparent power (one phase) VA 1626,6 ± 1,5 1352,6 ± 1,7 1581,9 ± 1,3Real power (sum) W 3954,20 ± 0,60 3943,1 ± 2,9 3747,1 ± 2,4
Dump loadVoltage (RMS) V 190,95 ± 0,28 34,61 ± 0,57 186,01 ± 0,26Trigger angle deg 90,4529 ± 0,0077 92,9 ± 2,7 91,9 ± 3,0
Hydraulic performanceInlet Pressure kPa 48,956 ± 0,013 48,926 ± 0,012 48,962 ± 0,015Turbine speed RPM 478,330 ± 0,080 481,43 ± 0,17 487,906 ± 0,094Discharge m3/s 0,1524281 ± 0,0000090 0,152409 ± 0,000012 0,152415 ± 0,000014Hydraulic power W 8361,2 ± 2,2 8355,4 ± 2,2 8361,214 ± 2,9Net head m 5,5893 ± 0,0014 5,5862 ± 0,0013 5,590 ± 0,0016
Table 6.2.3: Important parameters registered during the rapid on load situation
6.2.3 Rapid off-load situation
To simulate a rapid off-load situation, 4kW consumption load was disconnected(starting from 4kW ). The step responses in generator voltage (RMS) and frequencyare displayed in figure 6.2.6 and 6.2.5. Important hydraulic and electric parameterswere measured before and after the test and are given in table 6.2.4
Figure 6.2.5: Step response in generator voltage (RMS)
52
CHAPTER 6. RESULTS
Figure 6.2.6: Step response in frequency
Stable operating point - 4kW Stable operating point - 0kW Stable operating point - 4kWGeneratorFrequency Hz 51,1366 ± 0,0064 51,1349 ± 0,0094 51,1226 ± 0,0066Voltage (RMS) V 233,60 ± 0,22 230,00 ± 0,19 233,55 ± 0,20Current (RMS) A 5,6681 ± 0,0016 6,95726 ± 0,00053 5,7772 ± 0,0012Apparent power (one phase) VA 1324,0 ± 1,3 1600,2 ± 1,3 1349,3 ± 1,2Real power (sum) W 3873,9 ± 1,0 3836,23 ± 0,21 3936,89 ± 0,51
Dump loadVoltage (RMS) V 24,09 ± 0,36 187,86 ± 0,25 35,41 ± 0,30Trigger angle deg 92,254 ± 0,011 92,0 ± 3,0 148,00 ± 0,26
Hydraulic performanceInlet pressure kPa 48,951 ± 0,017 48,934 ± 0,010 48,923 ± 0,018Turbine speed RPM 485,32 ± 0,11 483,763 ± 0,066 481,370 ± 0,088Discharge m3/s 0,152377 ± 0,000018 0,1524120 ± 0,0000071 0,152412 ± 0,000010Hydraulic power W 8357,0 ± 3,2 8356,8 ± 1,7 8355,0 ± 2,8Net head mWc 5,5884 ± 0,0018 5,5870 ± 0,0011 5,5858 ± 0,0019
Table 6.2.4: Important parameters registered during the rapid off load situation
6.2.4 Overload signal/undervoltage
To simulate an overload situation, an extra heating element with capacity of 1kWwas connected. The test started with 4kW consumption loads, and when steadystate was obtained, the extra heating element was connected. The step responsesin frequency and generator voltage (RMS) are shown in figure 6.2.7 and 6.2.8. A2kW heating element was then introduced and a new similar test was accomplished.Connected consumption loads were then 6kW. The responses in frequency andvoltage are displayed in figure 6.2.10 and 6.2.9. Important parameters registeredduring the overload situations are given in table 6.2.5 and 6.2.6.
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CHAPTER 6. RESULTS
Figure 6.2.7: Step response in generator voltage (RMS)
Stable operating point - 4kW Stable operating point - 5kW Stable operating point - 4kWGeneratorFrequency Hz 51,1159 ± 0,0066 48,5069 ± 0,0076 51,1143 ± 0,0061Voltage (RMS) V 233,71 ± 0,19 218,75 ± 0,20 233,72 ± 0,19Current (RMS) A 5,7923 ± 0,0016 6,5536 ± 0,0009 5,7952 ± 0,0028Apparent power (one phase) VA 1353,7 ± 1,2 1433,6 ± 1,3 1354,5 ± 1,3Real power (sum) W 3944,59 ± 0,83 4195,81 ± 0,90 3945,9 ± 1,4
Dump loadVoltage (RMS) V 37,01 ± 0,35 0,0081 ± 0,0040 35,92 ± 0,29Trigger angle deg 146,76 ± 0,25 Inf ± - 147,74 ± 0,27
Hydraulic performanceInlet pressure kPa 48,972 ± 0,021 48,852 ± 0,012 48,935 ± 0,016Turbine speed RPM 481,225 ± 0,098 460,90 ± 0,10 481,32 ± 0,12Discharge m3/s 0,152519 ± 0,000025 0,1525160 ± 0,0000085 0,152449 ± 0,000013Hydraulic power W 8369,5 ± 4,5 8351,0 ± 2,0 8359,3 ± 2,9Net head mWc 5,5916 ± 0,0023 5,5794 ± 0,0013 5,5874 ± 0,0017
Table 6.2.5: Important parameters registered during overload situation with 1kW
Figure 6.2.8: Step response in frequency
54
CHAPTER 6. RESULTS
Figure 6.2.9: Step response in generator voltage (RMS)
Figure 6.2.10: Step response in frequency
55
CHAPTER 6. RESULTS
Stable operating point - 4kW Stable operating point - 6kW Stable operating point - 4kWGeneratorFrequency Hz 51,1183 ± 0,0071 45,1120 ± 0,0095 51,3378 ± 0,0078Voltage (RMS) V 233,76 ± 0,22 200,456 ± 0,056 231,42 ± 0,21Current (RMS) A 5,77608 ± 0,00062 7,4048 ± 0,0014 5,7734 ± 0,0023Apparent power (one phase) VA 1350,2 ± 1,3 1484,33 ± 0,57 1336,1 ± 1,4Real power (sum) W 3936,17 ± 0,24 4404,2 ± 1,5 3972,0 ± 1,1
Dump loadVoltage (RMS) V 34,97 ± 0,28 0,0073 ± 0,0040 25,90 ± 0,31Trigger angle deg 148,25 ± 0,24 inf ± - 334 ± 87
Hydraulic performanceInlet pressure kPa 48,908 ± 0,012 48,847 ± 0,018 48,959 ± 0,021Turbine speed RPM 481,359 ± 0,067 435,70 ± 0,17 482,74 ± 0,18Discharge m3/s 0,152406 ± 0,000010 0,152558 ± 0,000021 0,152527 ± 0,000022Hydraulic power W 8352,4 ± 2,0 8352,9 ± 3,3 8368,0 ± 3,8Net head mWc 5,5843 ± 0,0012 5,5791 ± 0,0019 5,5904 ± 0,0022
Table 6.2.6: Important parameters registered during overload situation with 2kW
56
CHAPTER 6. RESULTS
6.2.5 Run-away-test
A run-away test was carried out. The test started with 6kW dump loads and4kW consumption loads connected. Then, the fuses to the generator were blown.The runner accellerated rapidly from a constant speed of 487RPM to a speedof 710RPM ,i.e an increase of 45,8%. Because of weakness in the transmissionsystem, it was decided to reduce the sampling time for the run-away speed to avoiddamages. When a relative stable turbine speed was obtained, the pump speedand discharge of water was reduced. The response in the rotational speed of theturbine is shown in figure 6.2.11. Hydraulic parameters before and after the testwas performed are given in table 6.2.7.
Figure 6.2.11: Run-away speed
Stable operating point - 4kW Stable operating point - 4kWHydraulic performanceInlet pressure kPa 48,927 ± 0,031 48,859 ± 0,013Turbine speed RPM 486,62 ± 0,24 485,20 ± 0,11Discharge m3/s 0,152474 ± 0,000027 0,1523614 ± 0,0000079Hydraulic power W 8359,8 ± 5,7 8342,0 ± 1,9Net head mWc 5,5868 ± 0,0032 5,5791 ± 0,0013
Table 6.2.7: Hydraulic parameters registered before and after the run-away test
57
CHAPTER 6. RESULTS
6.3 Improvements of the Electronic load controller
There are several ways of improving the ELC. As seen from figure 6.2.2, the genera-tor signal is strongly affected by the triacs. A suggestion is to introduce pulse widthmodulation (PWM) or binary loads (BL). This will lead to a smoother output sig-nal and will improve the possibilities for using the dump load energy better. Whenusing phase angle regulation, the controller can only use resistive dump loads, dueto risk of unstability around 0V . By using binary loads, a smoother output signalis obtained. Developing a system with PWM will improve the output signal, andmake it possible to implement inductive or capacitive dump loads.
6.4 Connection with other energy sources
In this report, two other relevant renewable energy sources are described, namelyphotovolatic(PV)- and wind-energy. PV-energy is much utilised in remote areasand has technology that is easy to implement in a DC-setup with hydro power.The major drawbacks are low efficiency and no production during the night. Windenergy for small scale projects is not as much utilized as PV-energy. Comparedwith PV-, wind turbine systems have higher efficiency and produce energy bothday and night. Nevertheless, large forces and considerable mechanical stress areintroduced. Major drawbacks include wear in mechanical components and highermaintenance costs.
For a stand alone power system it is often essential to introduce several energysources and connect them in a hybrid energy system. With a hybrid system,the energy production becomes more reliable and stable. If one energy sourcefails, there is always a backup system. For a hybrid energy system in a remotearea, voltage regulation and DC-connection between the different energy sourcesis preferable. By implementing a battery bank with a charge controller, a moreflexible energy system is obtained. To handle top load, it is possible to connecta diesel generator. In figure 3.7.14 a hybrid energy system with a PV-moduleconnected to a hydropower plant is illustrated. An ELC is used for regulatingvoltage on the hydro power plant. The PV-module is connected to a DC-DC-converter with a MPPT-module to obtain maximum power output. A batterybank with a charge control is implemented to achieve more flexibility. If the energyplant and the village are located far apart, an inverter (DC/AC) is recommendedto reduce transmission losses.
A more complex hybrid energy system is given in figure 3.6.13. In this systemhydro-, wind- and PV-energy is connected in a DC-grid. The hydropower plant isconnected to the DC-grid via a rectifier (AC/DC-converter). For maximum poweroutput, the PV-module and the wind turbine is connected to a DC/DC-converterwith a MPPT-system. To handle top load, a diesel generator is connected. Abattery bank with charge control and a backup dump load system is implemented.
58
CHAPTER 6. RESULTS
The dump load system is only used to handle excess energy or in case of a fail-ure in the system. An energy management system is recommended for improvedperformance of the energy system.
59
CHAPTER 6. RESULTS
60
Chapter 7
Discussion
7.1 Performance of the experimental test rig
The cross-flow turbine from RHL and the synchronous generator from Bevi per-formed according to the spesifications during the experimental tests. This was notsurprising, since both generator and turbine were rather overrated with capacitiesof 20kW and 23kW . (Appendix B.1, [21])
The transmission system was the weak component in the experimental test rig. Dueto lack of time, price and availability, a belt drive system was chosen. Belt driveintroduces losses and will generally decrease the efficiency of the system. The designand dimensioning of the belt drive was based on experimental data from earlier testson the turbine. [21] In the earlier tests, an asynchronous generator with capacityof 55kW had been installed. Since the only experimental data available was fromthis configuration, the design was based on these values. The design criteria for thebelt drive was power output of 6kW , torque of 122-147Nm and a turbine speedof 400-450RPM . The generator speed was designed for 1500RPM . Gummi ogMaskinteknikk AS designed the transmission system. During the power test, itwas observed that the turbine speed was much higher than the design criteria.This resulted in slip in the belt drive. The friction between the belt pulley andthe belt was too small, resulting in slip and damage of the belt. By increasing thenumber of belts, the problem would have been solved, but due to time limitation itwas decided to use the existing belt and reduce power output from the generator.
During the testing, rotational speed of the turbine increased from 474 to 485RPM .After discussions with technicians in the Waterpower Laboratory, it was concludedthat the characteristic of the belt drive must have changed during the experimentaltests. [1] It was discovered that the belt had loosened during the testing. Inaddition, small amount of rubber dust was found beneath the belt drive. Rapidchanges in loads and many hours running the rig may have been factors that have
61
CHAPTER 7. DISCUSSION
contributed to this.
7.2 Performance of the ELC
7.2.1 Power test
The performance of the ELC was satisfying. However, only 2/3 of the capacitywas tested. Due to strict HSE-requirements, the controller had to be rebuilt beforethe testing could start. This resulted in a more robust and safe solution. Fortesting of the response in the governing system, the rebuilding was not affecting theresults. However, the general performance like overheating and quality of electroniccomponents and wiring, was no longer comparable.
In table 6.2.2 five different load situations have been evaluated. The hydraulicperformance was almost constant for the different situations. The deviation infrequency was 0.28Hz. In Norway the limit for deviation in frequency is ± 0.1Hz.Thus, the ELC did not fulfill this requirement. Since the deviation was rathersmall, it was not expected to influence standard user loads.
The design criteria for the generator voltage (RMS) was 230±5V . In the differentload situations, maximum deviation was 3.48V and the requirement was fulfilled.
The trigger angle increased with increasing consumption load. The correspondingdump load voltage was then reduced. According to the description given in section3.3, this verified the purpose and mode of operation for phase angle regulation.
7.2.2 Rapid on-load situation
When testing for a rapid on-load situation, a rapid increase in generator voltageand an abrupt short decrease in frequency was observed. In the frequency-plot,a minimum peak value of 50.4Hz was observed. This was a reduction of 1.4%compared with the stable values before starting the test. When comparing stableaveraged values before and after the test (0 and 4kW ), a reduction of 0.025Hz wascalculated. This was a very accurate and quick response and corresponded wellwith the expected response described in section 3.3.
In generator voltage (RMS), a maximum peak of 235.1V was detected. The stableaverage generator voltage increased with 3.4V after connecting the load. This waswithin the requirement given by RHL of 230±5V . The response in generator voltagewas different from what was expected in the analysis before the tests started.During this test a small overload of the system was observed. For an overloadsituation a reduction in generator voltage similar to a corresponding reduction infrequency was expected. This was discussed with Anders Austegard (the designerof the controller) but no clear reason has been identified.
62
CHAPTER 7. DISCUSSION
The logging of trigger angle did not work well and the values are not valid for thetest. The problem was related to peak detection in the LabView-program. Severalparameters had to be tuned in order to filter out noise in the generator signal. Thenoise was related to the triggering of the triacs.
During the test, turbine speed changed with 9.58 RPM (2.0%). Since the dischargeand inlet pressure (and thus the hydraulic power) was rather constant, it was prob-ably the characteristic of the transmission system that was changed. The increasedturbine speed resulted in a reduction in power output, meaning the efficiency wasreduced.
7.2.3 Rapid off-load situation
A sharp significant peak was observed in both generator voltage and frequencyduring the rapid off-load situation. The maximum value in frequency was 54.0Hzdeviating with 2.9Hz from the stable value after the test. This was a large andnoticeable deviation. However, the average value was reduced with only 0.0017Hzduring the test (4kW to 0kW ).
When the test started, it was observed that the system was slightly overloaded(similar to the rapid off-load situation). During the test, the average voltage value(RMS) decreased from 233,6V to 230,0V . Even if the mean value was withinthe voltage range, a single rapid peak of 242,5V , far beyond the maximum limit,was observed. This peak was damped shortly after, and the voltage was quicklystabilised. This kind of peaks can affect sensitive electronic equipments and is notdesirable.
The logging of trigger angle was not reliable during this test. The problem appearedwhen detecting large trigger angles and was similar to the previous test related tonoise in the generator voltage. This made it hard to obtain stable values sincemany outliers appeared.
The response in frequency corresponded well with the expected response describedin section 3.3. The response in generator voltage (RMS) was opposite of what wasexpected. The reason has, like for the previous test, not been detected.
7.2.4 Overload signal/undervoltage
Two overload-tests were performed. In the first test, the load was 125% of expectedpower output. This resulted in a reduction in frequency of 2,6Hz and a stableaverage value of 48,50Hz. The detected minimum peak was 47,5Hz. Similar tothe rapid on-load- and off-load tests, the system was slightly overloaded when thetest started. The average generator voltage decreased from 233,30V to 218,75Vduring this situation with a minimum peak of 213,6V .
63
CHAPTER 7. DISCUSSION
To evaluate the response of a large overload/undervoltage situation, the load wasincreased to 150% of power output. Similar to the first overload situation, gener-ator voltage and frequency dropped rapidly. The average generator value (RMS)decreased with 33,23V to 200,46V . A reduction from 51,12Hz to 45,11Hz (averagevalues) was observed in frequency. This is rapid changes that may disturb sensitiveelectronic equipment. However, an unstable situation did not appear. The responsein generator voltage and frequency match the expected response from section 3.3.1.
7.2.5 Run-away-test
In the run-away test, a stable turbine speed of approximately 710RPM was ob-served. This corresponded to 146% of the starting speed. Due to risk of damagingthe weak transmission system, this speed was not logged for more than 10s. Fora cross-flow turbine, run-away speed was expected to be approximately 200% ofnominal speed, but since a residual magnetic field still appeared in the generator,the torque on the generator was not equal to 0. [3] Thus, the run-away speed forthe turbine was not detected. The objective of the run-away test was to verify therobustness of the mechanical system. Even if no equipment was damaged, it wasevident that the test rig had weak components that needed to be improved beforefurther testing could be conducted.
7.3 Improvements of the electronic load controller
In this report two suggested improvements have been suggested, namely pulsewidth modulation (PWM) and binary loads (BL). For simple hydropower systemswith focus on cost and simpleness, phase angle regulation with triacs is a propersolution. The major disadvantages are the disharmonics in the generator voltageintroduced by the triacs, and the simple dump load system where only resistivedump loads can be utilised. By using binary dump loads (BL,) the disharmonicis removed. The major disadvantages with BL are the large number of resistivedump loads that need to be connected, and the inflexible dump load system. Byintroducing PWM and modern transistors, the problem with trigger response issolved. With this solution it is possible to connect both inductive and conductiveloads and thus utilise the dump load energy better. An implementation of PWMwill increase the cost of the controller, and may result in more stops in the energyproduction due to a potentially more complex circuit. Nevertheless, it will improvethe performance of the controller, increase the flexibility in the use of excess energyand will for further tests be recommended.
64
CHAPTER 7. DISCUSSION
7.4 Connection with other energy sources
Connecting several energy sources is the optimal solution for many energy projectsin remote areas. This results in a more flexible energy system and reduces thedependence on only one energy source. Connecting different energy sources with acommon DC-grid is the suggested solution. This will reduce costs and complexityof synchronization. Implementing a battery bank in a DC-grid is recommendedleading to increased flexibility and energy availability in the grid.
Two different hybrid energy systems are presented in this report. The first solution(see figure 3.7.14) utilises the existing ELC for controlling the output generatorvoltage in a hydro power plant. With this solution it is easy to obtain the correctDC voltage value by installing a simple rectifier. A PV-module is connected to aDC/DC-converter w/MPPT in order to obtain optimum performance and to setthe correct voltage level. A battery bank is connected to the DC-grid via a two-wayDC/DC-converter and a charge controller. If a wind turbine is more suitable, theconnection is almost similar to the PV-module, but with a rectifier implemented.To handle the top load, it is possible to connect a diesel generator via a rectifier.This is in a climatic perspective not recommended, but is a way of increasing theflexibility of the energy system and to avoid an oversized battery bank.
The hybrid energy system in figure 3.6.13 is a bit more sophisticated and complex.The ELC has been removed, and the generator voltage level in the hydro powerplant is controlled by a rectifier. The cost of the ELC compared to the rectifiermust be evaluated, but a more appropriate use of energy is introduced since thedump load energy is used for charging a large battery bank. Dump loads arestill required as emergency system, but less energy will dissipate this way. In thesuggested system, a PV-module and a wind-turbine is connected. This systemis rather flexible and reduces the requirement of installing a diesel generator tohandle the top load. However, to ensure energy availability a diesel generator maybe used as a stand-by generator to ensure energy access to vulnerable consumerslike a ward or a hospital if a failure occurs. To ensure optimum performanceof the energy system, it is suggested to develop an energy management system(EMS). This is suggested especially for larger energy systems, where the differencein performance is more evident.
65
CHAPTER 7. DISCUSSION
66
Chapter 8
Further work
The governing parameters in RHL’s ELCs are set equal in all projects. The param-eters are rather conservative chosen in order to prevent unstable situations. Tuningthe parameters for better response and to avoid single rapid peaks, as illustratedin the rapid on- and off-load tests, is suggested.
The synchronous generator was more expensive than expected. Using an inductiongenerator will reduce the costs and is a proper alternative. Until now, the ELC isonly designed for connection with synchronous generators. Developing a controllerfor connection with an induction generator is strongly advised.
Phase Angle Regulation with triacs are a rather simple way of governing the powerdiverted in the dump loads. From figure 6.2.2, it is evident that the harmonics of thetriacs influence the generator voltage strongly. By using a more sophisticate methodlike Pulse Width Modulation (PWM), this problem will be eliminated. Phase angleregulation has limitations in selecting dump loads. To prevent unstable situationsaround trigger angles of 0 and 180, only resistive dump loads can be connected.By introducing PWM, other dump loads (capacitive and inductive loads) may beimplemented. Designing and developing of an ELC with PWM, plus finding propersolutions for better use of the dump load energy is strongly recommended.
Finding proper, robust, low-cost solutions for connecting several energy sources isa very important task for the future. A suggestion for connecting hydro, wind,PV is set up in figure 3.6.13. It is focused on use of renewable energy sources, butwith the possibility of using energy from fossil fuel to cover the top load. Furtherinvestigation and evaluation of hybrid energy systems is suggested. In long term,testing the performance of a small scale system in laboratory may be possible.
Connecting a PV-module to the existing test rig is recommended and will be arealistic goal for new master thesis. A proposed setup is given in figure 3.7.14.
67
CHAPTER 8. FURTHER WORK
68
Chapter 9
Conclusion
The results from the experimental tests indicate that the electronic load controllerfrom Remote HydroLight performs well with stable regulation under different loadconditions. During the power test, several weaknesses in the experimental setupwere detected. The transmission system was underdimensioned and slip occured.The slip in the belt drive affected the measurements. During the tests, turbinespeed increased with 2.33%. Altered characteristic of the belt drive was expectedto be the reason. This resulted in a reduced power output and the tests were thusperformed with a slightly overloaded system. However, the general performance ofthe ELC was good without any overheating, noise or failure in components.
The results from the different load situations verified the principle of phase angleregulation. When consumption loads increased, dump load voltage (RMS) de-creased and trigger angle increased. The tests illustrated that the triacs affectedthe generator voltage signal each time the triacs triggered, i.e twice each periode.
The general response of the controller was good with stable average values and max-imum deviation of 0.025Hz and 3.6V in frequency and generator voltage (RMS)However, during the rapid on- and off-load tests a single short rapid peak wasdetected in both frequency and in the voltage measurement (RMS). The signalstabilised immediatly, but such large peaks in voltage and frequency might damagesensitive user loads.
To improve the performance of the electronic load controller, it is suggested tointroduce pulse width modulation (PWM). This will eliminate the influence fromthe triggering of the triacs. By using PWM, it will be possible to utilise the dumpload energy in a more appropriate manner by connecting inductive and conductivedump loads. With PWM, a battery bank can connected as dump load, resultingin a more flexible and stable energy system.
Two different suggestions for connecting several energy sources have been estab-lished. Both systems are based on a common DC-grid with charging of a battery
69
CHAPTER 9. CONCLUSION
bank. The first system uses existing test rig with ELC in connection with a PV-module and a battery bank. The other system is more complex and is connectinga hydro power plant (without using ELC) directly to a PV-module and a windturbine. An energy management system (EMS) is suggested to obtain optimumperformance of the energy system, and to ensure energy access to vulnerable con-sumers.
70
Bibliography
[1] Personal conversations with Joar Grilstad, Engineer - Waterpower Labora-tory,NTNU, 24.September 2013.
[2] Personal conversations with Lars Norum,Professor, NTNU, August 2013.
[3] Personal conversations with Anders Austegard,Sintef Energy, August andSeptember 2013.
[4] Personal conversations with Bjørn Winther Solemslie, Ph.D - Waterpower Lab-oratory,NTNU, June 2013.
[5] Anders Austegard. Electronic load control (elc) for synchronous generator.Technical report, Remote HydroLight, 2012.
[6] Godfrey Boyle. Renewable energy - power for a sustainable future. OxfordUniversity Press, 2004.
[7] A. Miraoui D. Fodorean, L. Szabo. Generator solutions for stand alone pico-electric power plants. In Electric Machines and Drives Conference, 3-6 May2009. IEMDC ’09. IEEE International, pages 434–438, 2009.
[8] NEK for International Electrotecnical Commision (IEC). Nek iec 60193 ver-sion 2.0 - hydraulic turbines, storage pumps and pump-turbines - model ac-ceptance tests. Technical report, Norwegian national comitee for InternationalElectrotecnical Commision, 1999.
[9] Ossberger Gmbh+Co. The ossberger turbine.http://www.ossberger.de/cms/en/hydro/the-ossberger-turbine-for-asynchronous-and-synchronous-water-plants/, -.
[10] National Instrument. Specifications for ni9225.
[11] Voltech instruments. Specifications for voltech pm3000a. User manual.
[12] Suprya Koirala. Analysis of the flow condition in a cross flow turbine. Technicalreport, Departement of Energy and Process Engineering, 2013.
[13] Embedded Lab. Pulse width modulation. http://embedded-lab.com/blog/?p=6033, 2012.
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[14] David B. Pengra and Thomas Dillman. Notes on data analysis and experi-mental uncertainty. Technical report, Ohio Wesleyan University, -.
[15] Jan Portegijs. The ’humming bird’ electronic load controller/inductiongenerator controller.http : //microhydropower.net/mhp group/portegijs/humbird/humb main.html,2012.
[16] Marton Ors. Maximum power point tracking for small scale wind turbinewith self-excited induction generator. Technical report, Napoca Departmentof Automatic Control, 2009.
[17] Owen Schumacher and Anders Austegard. Rhl/iam cross flow turbine. Tech-nical report, Remote HydroLight, -.
[18] H.Samad N.H.Minh S.R.Khandker, D.F.Barnes. Welfare impacts of rural elec-trification: Evidence from vietnam. Technical report, Astae,World Bank, 2008.
[19] Andrea Stranna. Hydraulic performance of a high head francis turbine. Mas-ter’s thesis, Norwegian University of Science and Technology, 2012.
[20] Eve Cathrin Walseth. Investigation of the flow through the runner of a cross-flow turbine. Master’s thesis, Norwegian University of Science and Technology,2009.
[21] Eve Cathrin Walseth and Sven Olaf Danielsen. Virkningsgradmaling av cross-flow turbin. Technical report, Departement of Energy and Process Engineer-ing, 2008.
72
Appendix A
Calibration
1
Calib
rato
r: Weig
hin
g ta
nk s
yste
mU
nit: F
low
mete
r, reg n
r. 462
4-7
( A03
361
33 )
Corre
cte
d w
eig
ht is
calc
ula
ted fro
m fo
rmula
a1
5,0
62
90
E-2
2w
here
para
mete
rs a
,b,c
,d a
nd e
is a
chie
ved
a2
-1,1
38
60
E-1
6th
rough s
ubstitu
ion c
alib
ratio
n.
a3
8,4
97
60
E-1
2
a4
-2,4
98
60
E-0
7
a5
1,0
01
50
E+
00
Manual
Observ
atio
n
befo
re
Manual
Observ
atio
n
afte
r
Manual
Observ
atio
n
Am
bie
nt
pre
ssure
Wate
r
tem
p
Air
tem
p
Calc
ula
ted
valu
e
befo
re
Calc
ula
ted
valu
e
afte
r
Diffe
rentia
l
weig
ht
Density
of w
ate
r
Density
of a
ir
Diffe
rentia
l
volu
me
Calc
ula
ted
Flo
w R
ate
Estim
ate
Devia
tion
Date
Weig
ht
Weig
ht
Volta
ge
Tim
eP
am
bT
WT
AW
eig
ht
Weig
ht
Weig
ht
rr
Volu
me
[kg]
[kg]
[V]
[s]
[kP
a]
[ oC]
[ oC]
[kg]
[kg]
[kg]
[kg/m
3][k
g/m
3][m
3][m
3/s]
[m3/s
][%
]
27.0
6.2
013
24524,8
24524,8
2,00
828335
61,0
00
27.0
6.2
013
24524,8
26926,5
2,40
231329
675,1
01
101,3
46
16,2
021,1
224518,8
26918,1
2399,3
998,9
618
1,2
006
2,4
0463
0,0
320187
0,0
3233
0,9
5037
27.0
6.2
013
26926,5
29112,2
2,54
638528
950,1
00
101,3
53
16,2
021,1
326918,1
29101,5
2183,5
998,9
618
1,2
006
2,1
8837
0,0
436800
0,0
4402
0,7
6434
27.0
6.2
013
31233,6
33434,1
2,75
188116
235,1
02
101,3
57
16,2
021,1
031220,8
33419,1
2198,3
998,9
618
1,2
008
2,2
0325
0,0
627672
0,0
6069
-3,4
2080
27.0
6.2
013
35733,9
38024,8
2,94
878483
130,1
01
101,3
55
16,2
221,1
035716,7
38005,5
2288,8
998,9
585
1,2
008
2,2
9391
0,0
762071
0,0
7667
0,6
0191
27.0
6.2
013
38024,8
40721,2
3,11
325073
230,1
01
101,3
57
16,2
621,0
838005,5
40699,5
2694,0
998,9
517
1,2
009
2,7
0005
0,0
896998
0,0
9001
0,3
4899
27.0
6.2
013
40721,2
43869,5
3,29
918665
130,1
01
101,3
55
16,3
021,0
340699,5
43845,0
3145,6
998,9
449
1,2
011
3,1
5270
0,1
047374
0,1
0510
0,3
4636
27.0
6.2
013
43869,5
47488,8
3,48
905099
330,1
01
101,3
53
16,3
021,0
343845,0
47461,3
3616,3
998,9
449
1,2
011
3,6
2447
0,1
204102
0,1
2051
0,0
8088
27.0
6.2
013
47488,8
51533,1
3,66
170402
330,1
02
101,3
49
16,3
221,0
247461,3
51502,3
4041,0
998,9
415
1,2
010
4,0
5014
0,1
345473
0,1
3452
-0,0
2222
27.0
6.2
013
51533,1
56019,9
3,84
431413
30,1
03
101,3
44
16,3
121,0
251502,3
55985,4
4483,0
998,9
432
1,2
010
4,4
9319
0,1
492605
0,1
4934
0,0
4990
27.0
6.2
013
22915,8
27900,0
4,04
836652
630,1
01
101,3
14
16,3
321,1
422911,4
27890,6
4979,1
998,9
398
1,2
001
4,9
9042
0,1
657891
0,1
6589
0,0
6236
27.0
6.2
013
27900,0
33300,1
4,21
824619
230,1
01
101,3
16
16,3
321,1
527890,6
33285,3
5394,7
998,9
398
1,2
001
5,4
0689
0,1
796250
0,1
7968
0,0
2905
27.0
6.2
013
33300,1
39148,6
4,40
205895
330,1
03
101,3
17
16,3
321,1
433285,3
39128,3
5843,0
998,9
398
1,2
002
5,8
5624
0,1
945400
0,1
9459
0,0
2697
27.0
6.2
013
39148,6
45467,2
4,59
441254
230,1
02
101,3
17
16,3
521,1
539128,3
45441,4
6313,1
998,9
364
1,2
001
6,3
2747
0,2
102010
0,2
1020
-0,0
0016
27.0
6.2
013
45467,2
52236,7
4,78
061994
330,1
01
101,3
21
16,3
521,1
345441,4
52205,3
6763,9
998,9
364
1,2
003
6,7
7929
0,2
252181
0,2
2531
0,0
4091
27.0
6.2
013
19502,2
26575,4
4,90
454002
530,1
01
101,2
87
16,4
421,1
719501,1
26567,3
7066,2
998,9
210
1,1
997
7,0
8236
0,2
352866
0,2
3537
0,0
3356
27.0
6.2
013
26575,4
34209,8
5,13
473183
730,1
02
101,2
76
16,4
321,1
826567,3
34194,1
7626,7
998,9
227
1,1
995
7,6
4413
0,2
539411
0,2
5404
0,0
4057
27.0
6.2
013
34209,8
42159,6
5,26
163991
330,1
03
101,2
67
16,4
221,1
734194,1
42136,6
7942,5
998,9
245
1,1
995
7,9
6064
0,2
644468
0,2
6434
-0,0
3968
27.0
6.2
013
42159,6
50661,4
5,48
968768
230,1
02
101,2
70
16,4
621,1
542136,6
50631,3
8494,7
998,9
176
1,1
996
8,5
1417
0,2
828438
0,2
8285
0,0
0096
27.0
6.2
013
50661,4
59633,5
5,68
039242
430,1
02
101,2
67
16,4
921,1
250631,3
59595,8
8964,4
998,9
125
1,1
997
8,9
8496
0,2
984840
0,2
9832
-0,0
5462
27.0
6.2
013
29923,6
38488,8
5,51
313263
230,1
02
101,2
60
16,5
221,1
629912,1
38469,1
8556,9
998,9
073
1,1
994
8,5
7659
0,2
849175
0,2
8475
-0,0
5920
27.0
6.2
013
38488,8
46120,0
5,13
390059
330,1
02
101,2
52
16,5
421,1
938469,1
46093,7
7624,6
998,9
038
1,1
992
7,6
4215
0,2
538752
0,2
5398
0,0
3997
27.0
6.2
013
46120,0
52116,5
4,45
946454
130,1
03
101,2
47
16,5
321,1
246093,7
52085,2
5991,6
998,9
056
1,1
994
6,0
0536
0,1
994937
0,1
9925
-0,1
2203
27.0
6.2
013
52116,3
56089,3
3,63
420959
230,1
03
101,2
35
16,5
521,1
052085,0
56054,7
3969,7
998,9
021
1,1
994
3,9
7880
0,1
321730
0,1
3229
0,0
8570
27.0
6.2
013
56088,7
58269,2
2,89
951274
530,1
02
101,2
22
16,5
321,0
756054,1
58232,7
2178,6
998,9
056
1,1
993
2,1
8359
0,0
725398
0,0
7267
0,1
7974
Ca
libra
tion c
onsta
nts
for w
eig
hin
g ta
nk
corre
ctio
n
Density
of w
ate
r is c
alc
ula
ted fro
m fo
rmula
Density
of a
ir is c
alc
ula
ted fro
m fo
rmula
Dis
charg
e is
found fro
m fo
rmula
WA
TE
RP
OW
ER
LA
BO
RA
TO
RY
Da
te:
27.0
6.2
013
Op
era
tor:
Calib
ratio
n S
heet
Øys
tein
Svein
sgje
rd H
veem
and C
hiye
mbekezo K
aunda
Calib
ratio
n o
f flow
mete
r
Com
ents
: T
he flo
w ra
te c
hanges d
urin
g c
alib
ratio
n.
The in
let c
onditio
ns to
the p
um
ps w
ill change d
ue to
less w
ate
r in th
e re
serv
oir.
54
32
54
32
mW
mW
mW
mW
Wa
bc
de
mW
3
a
(3,4837
10)
(273,15)
absp
21
(1)
am
m
WW
Q
t
106
72
87
3
1000
(14,6699
10)
810
(4
2,131891310
)6
10(
42,1318913
10)
m
absabs
absp
pp
C0
-0,1
6260647
C1
0,0
81143601
Calib
ratio
n c
onsta
nts
,
27.0
6.2
013
y =
0,0
811
68
79
8x - 0
,16
27
21
59
3
R² =
0,9
99
97
13
61
0,0
0
0,0
5
0,1
0
0,1
5
0,2
0
0,2
5
0,3
0
0,3
5
01
23
45
6
Flow Rate [m3/s]
Flo
w R
ate
Sig
nal [V
]
Flo
w R
ate
Calib
ratio
n
Calib
ration
of p
ressu
re tran
sdu
cer
Rig:
Op
erato
rs:
Date
:0
9.09.20
13
Pre
ssure (B
ar)
Vo
ltageP
ressu
re (kP
a)
01,90
615
9575
0
0,12,16
112
8619
10
0,22,48
012
6232
20
0,32,79
769
3241
30
0,43,11
777
6471
40
0,53,43
566
8945
50
0,63,75
142
2036
60
0,74,07
197
8219
70
0,84,39
269
6857
80
0,94,71
581
4905
90
15,03
288
6551
10
0
0,94,71
137
9191
90
0,84,39
216
1246
80
0,74,07
452
6935
70
0,63,75
637
4191
60
0,53,43
855
9693
50
0,43,11
588
7789
40
0,32,79
969
2932
30
0,22,47
760
9689
20
0,12,16
168
2027
10
01,90
618
8183
0
Ch
iyemb
ekezo K
au
nd
aØ
ystein S. H
veem
Cro
ss flow
turb
ine test rig
y = 31
,65
5x - 5
8,9
5 R
² = 0,9
99
7
0
20
40
60
80
100
120
01
23
45
6
Pressure (kPa)
Vo
ltage
Calib
ration
of p
ressu
re tran
sdu
cer
Pressu
re Calib
ration
Linear (P
ressure C
alibratio
n)
Appendix B
Instrumentation
B.1 Generator
5
tipo type
potenzarating
η 4/4p.f. = 1
potenzarating
η 4/4p.f. = 1
pesoweight
pesoweight
kVA % kVA % Kg Kg50 Hz - 3000 r.p.m. 60 Hz - 3600 r.p.m. IM B34 • IM B35 SAE 4 • SAE 5 • SAE 3
* KS 2 MAL 15 79 18,5 80 70 86* KS 2 MBL 17,5 80 22 82 90 106
KS 2 LAL 20 82 25 84 98 114 KS 2 LBL 25 84 31 86 117 133
50 Hz - 1500 r.p.m. 60 Hz - 1800 r.p.m. IM B34 • IM B35 SAE 4 • SAE 5* KS 4 MEL 11 80,8 13,2 81,2 71 87*KS 4 MFL 13,5 81,5 16,2 83,1 92 105KS 4 LEL 16 83,1 19,2 84,2 101 117KS 4 LFL 17,5 85,1 21 86,6 121 137
tipo type
potenzarating
η 4/4p.f. = 0,8
potenzarating
η 4/4p.f. = 0,8
pesoweight
pesoweight
kVA % kVA % Kg Kg50 Hz - 3000 r.p.m. 60 Hz - 3600 r.p.m. IM B34 • IM B35 SAE 4 • SAE 5 • SAE 3
* GS 2 MAS 22 83 27,5 84 76 92* GS 2 MBS 27 85 34 86 86 102
GS 2 LAS 31,5 86 40 87 101 117 GS 2 LBS 38 88 47,5 89 122 138
50 Hz - 1500 r.p.m. 60 Hz - 1800 r.p.m. IM B34 • IM B35 SAE 4 • SAE 5* GS 4 MES 16,5 84,5 19,8 85,3 78 93*GS 4 MFS 20 87 24 88,2 92 108GS 4 LES 25 88 30 89 110 126GS 4 LFS 30 89,2 36 90,1 131 147
KS
* solo in SAE 3 • only in SAE 3
* solo in SAE 3 • only in SAE 3
GS
Alternatori sincroni monofasi a 2 e 4 poli autoregolati senza spazzole> Protezione: IP 21.> Tensione standard: 115/230 V - 50 Hz.> Corrente di cortocircuito superiore a 3 In.> Forme costruttive: IM B34 - B3/B14, IM B35 B3/B9, IM B35 - J609b, SAE 3, SAE 4, SAE 5.
Alternatori sincroni trifasi a 2 e 4 poli autoregolati con spazzole> Protezione: IP 21.> Tensione standard: 231/400 V - 50 Hz.> Corrente di cortocircuito superiore a 3,5 In.> Forme costruttive: IM B34 - B3/B14, IM B35 B3/B9, IM B35 - J609b, SAE 3, SAE 4, SAE 5.
Single -phase synchronous self-regulated brushless 2 and 4 poles alternators.> Protection: IP 21.> Standard voltage: 115/230 V - 50 Hz.> Short circuit current greater than 3 In.> Shape: IM B34 - B3/B14, IM B35 B3/B9, IM B35 - J609b, SAE 3, SAE 4, SAE 5.
Three -phase synchronous self-regulated brushes 2 and 4 poles alternators.> Protection: IP 21.> Standard voltage: 231/400 V - 50 Hz.> Short circuit current greater than 3,5 In.> Shape: IM B34 - B3/B14, IM B35 B3/B9, IM B35 - J609b, SAE 3, SAE 4, SAE 5.
seriesKS GS
KS / GS • Synchronous single-phase and three-phase alternators
Serie KS / GS - Dimensioni di ingombro Overall dimensions - KS / GS series
serie
s KS
/ GS
-11/
2010
E60
Ø35
k6
Ø 1
4
pd
Ø 1
80Ø
250
Ø 2
50pd
pG Q
Ø 2
5010
3847
52
1:5
30 a
ab
Ø 14
Ø 14
2 1/4 x foot
52
125
9
Ø 14Ø
14
Ø 1
55
D
D
A
A
5
129
129
D
A129
C
A
L
129
I
g
N.F
ori Ø
R
I
N.F
ori Ø
R
45°
30°
N.F
ori Ø
R1
N.F
ori Ø
R
II1
S
S1
tipo - type dimensioni - dimensionsA D E
[mm] [mm] [mm]KS - L / GS - L 597 481 662
forma costruttiva / shape IM B34 - B3/B14 cod.E
albero - shaft flangia - flange cod.d a I p N. fori R g30 16 135 105 12 9 30° B38 5 150 125 4 12 90° G
E60
Ø35
k6
Ø 1
4
pd
Ø 1
80Ø
250
Ø 2
50pd
pG Q
Ø 2
5010
3847
52
1:5
30 a
ab
Ø 14
Ø 14
2 1/4 x foot
52
125
9
Ø 14Ø
14
Ø 1
55
D
D
A
A
5
129
129
D
A129
C
A
L
129
I
g
N.F
ori Ø
R
I
N.F
ori Ø
R
45°
30°
N.F
ori Ø
R1
N.F
ori Ø
R
II1
S
S1
tipo - type dimensioni - dimensionsA D
[mm] [mm]KS - L / GS - L 592 481
forma costruttiva / shape IM B35 - B3/B9 cod.B/G
E60
Ø35
k6
Ø 1
4
pd
Ø 1
80Ø
250
Ø 2
50pd
pG Q
Ø 2
5010
3847
52
1:5
30 a
ab
Ø 14
Ø 14
2 1/4 x foot
52
125
9
Ø 14
Ø 1
4
Ø 1
55
D
D
A
A
5
129
129
D
A129
C
A
L
129
I
gN
.For
i Ø R
I
N.F
ori Ø
R
45°
30°
N.F
ori Ø
R1
N.F
ori Ø
R
II1
S
S1
tipo - type dimensioni - dimensionsA C
[mm] [mm]KS - M / GS - M 545 481KS - L / GS - L 644 580
SAE flangia - flangeQ P I N. fori R1 S
3 452 409,6 428,6 12 11 15°4 405 362 381 12 11 15°5 358 314,3 333,4 8 11 22° 30°
SAE giunto a dischi - disk jointL G I1 N. fori R S1
6,5 30,2 215,9 200 6 9 60°7,5 30,2 241,3 222,2 8 9 45°8 62 263,5 244,5 6 11 60°10 53,8 314,3 295,3 8 11 45°
11,5 39,5 352,4 333,4 8 11 45°
forma costruttiva / shape SAE cod. 4/5
E60
Ø35
k6
Ø 1
4
pd
Ø 1
80Ø
250
Ø 2
50pd
pG Q
Ø 2
5010
3847
52
1:5
30 a
ab
Ø 14
Ø 14
2 1/4 x foot
52
125
9
Ø 14
Ø 1
4
Ø 1
55
D
D
A
A
5
129
129
D
A129
C
A
L
129
I
gN
.For
i Ø R
I
N.F
ori Ø
R
45°
30°
N.F
ori Ø
R1
N.F
ori Ø
R
II1
S
S1
tipo - type dimensioni - dimensionsA D
[mm] [mm]KS - L / GS - L 592 481
albero - shaft cod.d a b
25,4 63,5 45 D35 12,4 71 F
forma costruttiva / shape IM B35 - J609b cod. F
flangia - flangeI p N. fori R
165 146,1 4 11197 163,6 4 11197 177,8 4 11
Soga S.p.A. • Via Della Tecnica, 15 • 36075 Montecchio Maggiore (VI) • ITALYOperating office• Via Tezze, 3 • 36073 Cereda di Cornedo Vicentino (VI) • ITALYPh. +39 0445 450500 • Fax +39 0445 446222 • [email protected] Subsidiary • Soga Electric Group S.L.• Pol. Ind. Casa Grande Apartado 213 • Torrevieja • SPAINPh. +34 96 5705656 • Fax +34 96 5705500 • [email protected]
B.2 ELC
8
1 2 3 4 5 6
Tilkoblingsliste
Page 1
Ekstern Klemme Beskrivelse Vern LastbryterG1:U X1:1 L1 fra generator
F1G1:V X1:2 L2 fra generatorG1:W X1:3 L3 fra generatorG1:N X1:4 N fra generatorR1:L X3:1
F2 S1R1:N X3:2R2:L X3:3
F3 S2R2:N X3:4R3:L X3:5
F4 S3R3:N X3:6R4:L X3:7
F5 S4R4:N X3:8R5:L X3:9
F6 S5R5:N X3:10R6:L X3:11
F7 S6R6:N X3:12R7:L X3:13
F8 S7R7:N X3:14AI0:L X4:1 Generatorspenning til DAQ – L
F10AI0:N X4:2 Generatorspenning til DAQ – NAI1:L X4:3 Lastspenning til DAQ – L
F11AI1:N X4:4 Lastspenning til DAQ – N
Dumplast L1, styrt via ELC/triac, 2kW
Dumplast L2, styrt via ELC/triac, 2kW
Dumplast L3, styrt via ELC/triac, 2kW
Forbrukslast L1, 2kW
Forbrukslast L2, 2kW
Forbrukslast L3, 2kW
Forbrukslast L3, 1kW
B.2.1 Estimated price
11
Cost estimate of ELC- Remote HydroLight
The following cost calculation is done for a 6 kW ELC with single card:
What Number Price each Tot
Part Work + wires
Heat sink 2 200 250 900
TRIAC 3 300 150 1350
Digital card 3 phase 1 1450 1200 2650
Coil 3 80 90 510
Transformer 1 220 200 420
Varistor 1 35 0 35
Box, wood + front plate 1 1000 0 1000
Fuse 3 310 240 1650
Voltmeter 2 140 100 480
Connector 3 phase 2 700 0 1400
SUM Afs 10395
USD 208
NOK 1248
USD has rate 50 Afs/USD
NOK (Norwegian kroner) has rate 6 NOK/USD
This is the cost in Afghanistan when delivered from the shop making the ELC either
bought by me (Anders Austegard) or the village people from the Industry. Bought by
other NGOs must assume a higher price.
The price for a 3 phase ELC with double cards with capacity P [kW] becomes about:
Price = 10 000 Afs+ P * 600 Afs/kW. Eventually ampere meters increase the price.
In addition comes the water heater with a total price of around 200 USD.
Anders Austegard
Remote HydroLight
www.remotehydrolight.com
B.3 Heating elements
13
"Datasheet Backer Heater"
Datablad Backer Varmekolbe
Heater To heat
Varmekolbe type: IU 25 For oppvarming av: Vann
Power Voltage
Total effekt: 1000W Spenning: 230 V
Immerson lenght Unheated
Instikkkslengde "B": 160mm Innaktiv sone "C": 20 mm
Heated Flange/Screw plug
Varm kolbe "D": 140mm Flens/hode: R 1 1/4" BSP
Element Pcs Surface loading
Rør type: 9SF7 Antall: 2 Overfl.belastning 8,8 W/cm
Terminal box
Koblingsboks type: K7
Total length incl. terminal box
Total lengde inkl. koblingsboks "A": 234mm
95
115
Total length "A"
Immersion length "B"
74 Unheated "C" Heated sone "D"
2
"Datasheet Backer Heater"
Datablad Backer Varmekolbe
Heater To heat
Varmekolbe type: IU 27 For oppvarming av: Vann
Power Voltage
Total effekt: 2000 W Spenning: 230 V
Immerson lenght Unheated
Instikkkslengde "B": 250 mm Innaktiv sone "C": 35mm
Heated Flange/Screw plug
Varm kolbe "D": 215 mm Flens/hode: R 1 1/4" messing
Element Pcs Surface loading
Rør type: 8,5 mm SS 2348 Antall: 2 Overfl.belastning 8,5 W/cm
Terminal box
Koblingsboks type: K 7
Total length incl. terminal box
Total lengde inkl. koblingsboks "A": 324mm
95
115
Total length "A"
Immersion length "B"
74 Unheated "C" Heated sone "D"
2
16
Appendix C
Data aquistion-program
C.1 LabVIEW-program
17
Figure C.1.1: Front panel of LabView program for hydraulic performance. Due toa very large block diagram it was not possible to view the whole program. See
18
Figure C.1.2: Front panel of LabView program (tab 1) for ELC with processing ofdump load- and generator voltage signals. Due to a very large block diagram itwas not possible to view the whole program
19
Figure C.1.3: Front panel of LabView program(tab 2) for ELC with only dumpload- and generator voltage signals plotted. Due to a very large block diagram itwas not possible to view the whole program
20
Appendix D
Experimental data
21
Diffe
ren
t load
situatio
ns
Freq
uen
cy Gen
era
tor
Hz
51,167±
0,01051,149
±0,013
51,207±
0,01651,3903
±0,0090
51,1139±
0,0089
Am
plitu
de G
en
erato
r Vo
ltageV
350,31±
0,17367,30
±0,20
378,37±
0,49354,067
±0,0
55359
,768±
0,051
Gen
era
tor R
MS-V
oltage
V230,42
±0,24
231,04±
0,24230,33
±0,23
229,54±
0,23233,4
7±
0,27
Ab
solu
te mean
Gen
erato
rV
202,29±
0,29202,84
±0,29
202,11±
0,28201,21
±0,27
203,44
±0,31
Am
plitu
de d
um
p lo
adV
348,888±
0,070344,44
±0,13
313,39±
0,26288,94
±0,43
175,10
±0,90
RM
S Vo
ltage du
mp
load
V193,37
±0,33
166,86±
0,34138,62
±0,42
104,39±
0,3148,10
±0,32
Trigger angle
deg
90,467±
0,010112,96
±0,20
117,94±
0,17122,37
±0,18
141,12
±0,82
Re
al po
wer
W4050,0
±1,2
4068,78±
0,724093,30
±0,50
4096,95±
0,38412
7,17±
0,43
Cu
rrent (R
MS)
A7,1544
±0,0012
7,3210±
0,00107,22265
±0,00083
6,88715±
0,00081
6,2100
±0,0011
Ap
pare
nt p
ow
erV
A1648,5
±1,8
1691,4±
1,81663,6
±1,7
1580,9±
1,61449,8
±1,7
Pre
ssure
kPa
49,034±
0,01348,962
±0,014
49,013±
0,01448,958
±0,0
1648,95
2±
0,012
Tem
pera
ture
deg
C14,603066
±0,000086
14,60520±
0,0001014,60770
±0,00011
14,61147±
0,00014
14,616
06±
0,00012
Gen
era
tor sp
eed
RP
M474,140
±0,081
474,571±
0,089475,910
±0,088
478,14±
0,11476
,229±
0,088
Disch
argem
3/s0,152541
±0,000016
0,152490±
0,0000170,152487
±0,000011
0,152483±
0,000013
0,1524171
±0,0
000094
Ned
-17,2651
±0,0029
17,2925±
0,002717,3334
±0,0027
17,4232±
0,0029
17,3553±
0,0029
Qed
-0,282200
±0,000033
0,282298±
0,0000270,282164
±0,000036
0,282296±
0,000043
0,2822
01±
0,000032
Po
wer_
hyd
rW
8380,4±
2,58366,1
±3,0
8373,6±
2,58365,1
±2,8
8359,8±
2,1
Pre
ssure
_pa
Pa
49034±
1348962
±14
49013±
1448958
±16
48952
±12
Ve
locity_in
letm
/s3,10755
±0,00032
3,10650±
0,000353,10644
±0,00022
3,10636±
0,00026
3,10501
±0,00019
H_n
etm
5,5980±
0,00145,5903
±0,0015
5,5954±
0,00155,5899
±0,0017
5,5888
±0,0012
Den
sitykg
/m3
999,237387±
0,000014999,237038
±0,000018
999,236685±
0,000017999,236098
±0,00002
0999,2
35407±
0,000019
0kW
1kW2kW
3kW4kW
Rap
id o
n lo
ad s
itu
atio
n
Fre
qu
en
cy G
en
era
tor
Hz
51,145
±0,010
51,1205
±0,0058
51,142
±0,010
Am
plit
ud
e G
en
era
tor
Vo
ltag
eV
351,80
±0,42
358,969
±0,093
362,20
±0,54
Ge
ne
rato
r R
MS-
Vo
ltag
e
V230,16
±0,21
233,60
±0,19
230,15
±0,18
Ab
solu
te m
ean
Ge
ne
rato
rV
202,08
±0,25
203,44
±0,23
202,16
±0,21
Am
plit
ud
e d
um
p lo
adV
348,244
±0,069
131,8
±1,9
347,117
±0,068
RM
S V
olt
age
du
mp
load
V190,95
±0,28
34,61
±0,57
186,01
±0,26
Trig
ger
angl
ed
eg90,4529
±0,0077
92,9
±2,7
91,9
±3,0
Re
al p
ow
er
W3954,20
±0,60
3943,1
±2,9
3747,1
±2,4
Cu
rre
nt
(RM
S)A
7,06716
±0,00074
5,790
±0,005
6,8733
±0,0023
Ap
par
en
t p
ow
er
VA
1626,6
±1,5
1352,6
±1,7
1581,9
±1,3
Pre
ssu
rekP
a48,956
±0,013
48,926
±0,012
48,962
±0,015
Tem
pe
ratu
red
eg C
14,62569
±0,00014
14,63875
±0,00016
14,65783
±0,00018
Ge
ne
rato
r sp
ee
dR
PM
478,330
±0,080
481,432
±0,175
487,906
±0,094
Dis
char
gem
3/s
0,1524281
±0,0000090
0,152409
±0,000012
0,152415
±0,000014
Ne
d-
17,4310
±0,0026
17,5491
±0,0067
17,7792
±0,0037
Qe
d-
0,282208
±0,000037
0,282253
±0,000032
0,282171
±0,000034
Po
we
r_h
ydr
W8361,2
±2,2
8355,4
±2,2
8361,2
±2,9
Pre
ssu
re_p
aP
a48956
±13
48926
±12
48962
±15
Ve
loci
ty_i
nle
tm
/s3,10524
±0,00018
3,10486
±0,00024
3,10497
±0,00029
H_n
et
m5,5893
±0,0014
5,5862
±0,0013
5,5899
±0,0016
De
nsi
tykg
/m3
999,233968
±0,000023
999,231996
±0,000025
999,229146
±0,000025
Stab
le o
pe
rati
ng
po
int
- 0
kWSt
able
po
int
afte
r ch
ange
- 4
kWSt
able
op
era
tin
g p
oin
t 2
-0
kW
Rap
id o
ff load
situatio
n
Freq
ue
ncy G
en
erato
rH
z51,1366
±0,0064
51,1349
±0,0094
51,1226
±0,0066
Am
plitu
de
Ge
ne
rator V
oltage
V357,722
±0,152
357,753
±0,569
359,327
±0,041
Ge
ne
rator R
MS-V
oltage
V
233,60
±0,22
230,00
±0,19
233,55
±0,20
Ab
solu
te m
ean
Ge
ne
rator
V203,43
±0,26
201,95
±0,23
203,38
±0,24
Am
plitu
de
du
mp
load
V99,34
±0,98
347,525
±0,058
134,5
±1,0
RM
S Vo
ltage d
um
p lo
adV
24,09
±0,36
187,86
±0,25
35,41
±0,30
Trigger an
gled
eg92,254
±0,011
92,0
±3,0
148,00
±0,26
Re
al po
we
rW
3873,9
±1,0
3836,23
±0,21
3936,89
±0,51
Cu
rren
t (RM
S)A
5,6681
±0,0016
6,9573
±0,0005
5,7772
±0,0012
Ap
pare
nt p
ow
er
VA
1324,0
±1,3
1600,2
±1,3
1349,3
±1,2
Pre
ssure
kPa
48,951
±0,017
48,934
±0,010
48,923
±0,018
Tem
pe
rature
deg
C14,67053
±0,00020
14,68580
±0,00022
14,70723
±0,00019
Ge
ne
rator sp
ee
dR
PM
485,32
±0,11
483,763
±0,066
481,370
±0,088
Disch
argem
3/s
0,152377
±0,000018
0,1524120
±0,0000071
0,152412
±0,000010
Ne
d-
17,6873
±0,0035
17,6327
±0,0022
17,5473
±0,0026
Qe
d-
0,282136
±0,000042
0,282237
±0,000026
0,282267
±0,000053
Po
we
r_hyd
rW
8357,0
±3,2
8356,8
±1,7
8355,0
±2,8
Pre
ssure
_pa
Pa
48951
±17
48934
±10
48923
±18
Ve
locity_in
let
m/s
3,10419
±0,00036
3,10491
±0,00015
3,10491
±0,00021
H_n
et
m5,5884
±0,0018
5,5870
±0,0011
5,5858
±0,0019
De
nsity
kg/m
3999,227233
±0,000029
999,224928
±0,000033
999,221695
±0,000028
Stable
op
eratin
g po
int - 4
kWStab
le o
pe
rating p
oin
t - 0kW
Stable
op
eratin
g po
int 2
- 4kW
Ove
rlo
ad s
itu
atio
n-
1kW
Fre
qu
en
cy G
en
era
tor
Hz
51,1159
±0,0066
48,5069
±0,0076
51,1143
±0,0061
Am
plit
ud
e G
en
era
tor
Vo
ltag
eV
359,410
±0,046
337,230
±0,053
359,318
±0,040
Ge
ne
rato
r R
MS-
Vo
ltag
e
V233,71
±0,19
218,75
±0,20
233,72
±0,19
Ab
solu
te m
ean
Ge
ne
rato
rV
203,59
±0,23
190,46
±0,24
203,61
±0,23
Am
plit
ud
e d
um
p lo
adV
140,4
±1,2
0,0252
±0,0040
136,6
±1,0
RM
S V
olt
age
du
mp
load
V37,01
±0,35
0,0081
±0,0040
35,92
±0,29
Trig
ger
angl
ed
eg146,76
±0,25
Inf
±147,74
±0,27
Re
al p
ow
er
W3944,59
±0,83
4195,81
±0,90
3945,9
±1,4
Cu
rre
nt
(RM
S)A
5,7923
±0,0016
6,55356
±0,00087
5,7952
±0,0028
Ap
par
en
t p
ow
er
VA
1353,7
±1,2
1433,6
±1,3
1354,5
±1,3
Pre
ssu
rekP
a48,972
±0,021
48,852
±0,012
48,935
±0,016
Tem
pe
ratu
red
eg C
14,71519
±0,00021
14,72397
±0,00014
14,73272
±0,00025
Ge
ne
rato
r sp
ee
dR
PM
481,225
±0,098
460,90
±0,10
481,32
±0,12
Dis
char
gem
3/s
0,152519
±0,000025
0,1525160
±0,0000085
0,152449
±0,000013
Ne
d-
17,5330
±0,0026
16,8109
±0,0030
17,5433
±0,0041
Qe
d-
0,282319
±0,000041
0,282623
±0,000033
0,282297
±0,000039
Po
we
r_h
ydr
W8369,5
±4,5
8351,0
±2,0
8359,3
±2,9
Pre
ssu
re_p
aP
a48972
±21
48852
±12
48935
±16
Ve
loci
ty_i
nle
tm
/s3,10709
±0,00052
3,10703
±0,00017
3,10567
±0,00026
H_n
et
m5,5916
±0,0023
5,5794
±0,0013
5,5874
±0,0017
De
nsi
tykg
/m3
999,220514
±0,000027
999,219136
±0,000022
999,217851
±0,000037
Stab
le o
pe
rati
ng
po
int-
4kW
Stab
le p
oin
t af
ter
chan
ge-5
kWSt
able
op
era
tin
g p
oin
t 2
-4kW
Ove
rload
situatio
n- 2
kW
Freq
ue
ncy G
ene
rato
rH
z51,1183
±0,0071
45,1120
±0,0095
51,3378
±0,0078
Am
plitu
de
Ge
ne
rato
r Vo
ltageV
359,234
±0,046
308,699
±0,063
352,140
±0,099
Gen
era
tor R
MS-V
oltage
V
233,76
±0,22
200,456
±0,056
231,42
±0,21
Ab
solu
te me
an G
ene
rato
rV
203,64
±0,26
174,614
±0,057
201,66
±0,25
Am
plitu
de
du
mp
load
V133,2
±1,0
0,0202
±0,0040
99,45
±0,87
RM
S Vo
ltage d
um
p lo
adV
34,97
±0,28
0,0073
±0,0040
25,90
±0,31
Trigger angle
deg
148,25
±0,24
inf
±334
±87
Re
al po
wer
W3936,17
±0,24
4404,2
±1,5
3972,0
±1,1
Cu
rren
t (RM
S)A
5,7761
±0,0006
7,4048
±0,0014
5,7734
±0,0023
Ap
pa
ren
t po
we
rV
A1350,2
±1,3
1484,33
±0,57
1336,1
±1,4
Pre
ssure
kPa
48,908
±0,012
48,847
±0,018
48,959
±0,021
Tem
pe
ratu
red
eg C
14,73804
±0,00014
14,74489
±0,00019
14,75302
±0,00020
Gen
era
tor sp
ee
dR
PM
481,359
±0,067
435,70
±0,17
482,74
±0,18
Disch
arge
m3
/s0,152406
±0,000010
0,152558
±0,000021
0,152527
±0,000022
Ne
d-
17,5493
±0,0027
15,8922
±0,0050
17,5900
±0,0052
Qe
d-
0,282293
±0,000032
0,282707
±0,000055
0,282366
±0,000057
Po
wer_h
ydr
W8352,4
±2,0
8352,9
±3,3
8368,0
±3,8
Pre
ssure_p
aP
a48908
±12
48847
±18
48959
±21
Velo
city_inlet
m/s
3,10479
±0,00021
3,10789
±0,00044
3,10725
±0,00044
H_n
et
m5,5843
±0,0012
5,5791
±0,0019
5,590
±0,0022
Den
sitykg
/m3
999,217034
±0,000021
999,215973
±0,000029
999,214791
±0,000031
Stab
le op
era
ting p
oin
t -4kW
Stab
le po
int after ch
an
ge - 6
kWStab
le op
era
ting p
oin
t 2 -4
kW
Ru
n-a
way
sp
eed
Stab
le o
pe
rati
ng
po
int
Stab
le o
per
atin
g p
oin
t 2
Pre
ssu
rekP
a48,927
±0,031
48,859
±0,013
Tem
per
atu
red
eg C
14,76172
±0,00020
14,76722
±0,00020
Gen
erat
or
spee
dR
PM
486,62
±0,24
485,20
±0,11
Dis
char
gem
3/s
0,152474
±0,000027
0,1523614
±0,0000079
Ned
-17,7373
±0,0055
17,6978
±0,0036
Qed
-0,282358
±0,000070
0,282344
±0,000037
Po
wer
_hyd
rW
8359,8
±5,7
8342,0
±1,9
Pre
ssu
re_p
aP
a48927
±31
48859
±13
Vel
oci
ty_i
nle
tm
/s3,10618
±0,00055
3,10388
±0,00016
H_n
etm
5,5868
±0,0032
5,5791
±0,0013
De
nsi
tykg
/m3
999,213458
±0,000031
999,212596
±0,000031
28
Appendix E
HSE-repport for experiment
29
Risk Assessment Report
Cross flow turbine connected to ELC
Prosjektnavn Crossflow Turbine connected to ELC
Apparatur Crossflow Turbine, Electronic load controller
Enhet NTNU
Apparaturansvarlig Bård Brandåstrø
Prosjektleder Torbjørn Nielsen
HMS-koordinator Morten Grønli
HMS-ansvarlig (linjeleder) Olav Bolland
Plassering Waterpower Laboratory
Romnummer Room 21
Risikovurdering utført av Øystein Sveinsgjerd Hveem, Magni Fjørtoft Svarstad, Kristin Gjevik, Chiyembekezo Kaunda, Peter Joachim Gogstad, Bård Brandåstrø
Approval:
Navn Dato Signatur
Prosjektleder Torbjørn Nielsen
HMS koordinator Morten Grønli
HMS ansvarlig (linjeleder)
Olav Bolland
TABLE OF CONTENTS
1 INTRODUCTION ............................................................................................................... 1
2 CONCLUSION ................................................................................................................... 1
3 ORGANISATION ............................................................................................................... 1
4 RISK MANAGEMENT IN THE PROJECT ............................................................................. 1
5 DESCRIPTIONS OF EXPERIMENTAL SETUP ....................................................................... 2
6 EVACUATION FROM THE EXPERIMENTAL AREA ............................................................. 3
7 WARNING ........................................................................................................................ 3
7.1 Before experiments ......................................................................................................... 3
7.2 Non-conformance ........................................................................................................... 3
8 ASSESSMENT OF TECHNICAL SAFETY .............................................................................. 4
8.1 HAZOP .............................................................................................................................. 4
8.2 Flammable, reactive and pressurized substances and gas ............................................. 4
8.3 Pressurized equipment .................................................................................................... 4
8.4 Effects on the environment (emissions, noise, temperature, vibration, smell) ............. 5
8.5 Radiation ......................................................................................................................... 5
8.6 Chemicals......................................................................................................................... 5
8.7 Electricity safety (deviations from the norms/standards) .............................................. 5
9 ASSESSMENT OF OPERATIONAL SAFETY ......................................................................... 5
9.1 Procedure HAZOP ............................................................................................................ 5
9.2 Training of operators ....................................................................................................... 5
9.3 Technical modifications ................................................................................................... 6
9.4 Personal protective equipment ....................................................................................... 6
9.4.1 General Safety .................................................................................................. 6
9.5 Safety equipment ............................................................................................................ 7
9.6 Special preparations ........................................................................................................ 7
10 QUANTIFYING OF RISK - RISK MATRIX............................................................................. 7
11 REGULATIONS AND GUIDELINES ..................................................................................... 8
12 DOCUMENTATION ........................................................................................................... 9
13 GUIDANCE TO RISK ASSESSMENT TEMPLATE ................................................................. 9
1
1 INTRODUCTION
The experimental test rig is under construction with a cross flow turbine connected to a synchronous generator where an Electronic Load Controller (ELC) is used as governing system. The motivation of the experiment is to investigate the performance, stability and measure the response time of the ELC manufactured by Remote HydroLight/Anders Austegard. The rig is located in Room 21 of the Waterpower laboratory.
2 CONCLUSION
The experimental setup is approved Apparaturkort (UNIT CARD) is valid for 12 months Forsøk pågår kort (EXPERIMENT IN PROGRESS) is valid for 12 months
3 ORGANISATION
Rolle
Prosjektleder Torbjørn Nielsen
Apparaturansvarlig Bård Brandåstrø
Romansvarlig Halvor Haukvik
HMS koordinator Morten Grønli
HMS ansvarlig (linjeleder): Olav Bolland
4 RISK MANAGEMENT IN THE PROJECT
Hovedaktiviteter risikostyring Nødvendige tiltak, dokumentasjon DATE
Prosjekt initiering Prosjekt initiering mal
Veiledningsmøte Guidance Meeting
Skjema for Veiledningsmøte med pre-risikovurdering
Innledende risikovurdering Initial hazard assessment
Fareidentifikasjon – HAZID Skjema grovanalyse
Evaluation of technical security Prosess-HAZOP Tekniske dokumentasjoner
Evaluation of operational safety Prosedyre-HAZOP Opplæringsplan for operatører
Final assessment, quality assurance Uavhengig kontroll Utstedelse av apparaturkort Utstedelse av forsøk pågår kort
2
5 DESCRIPTIONS OF EXPERIMENTAL SETUP
Give a short description of the experimental setup and the purpose of the experiments The purpose with this experiment is to analyse the performance of an electronic load controller (ELC) manufactured by Remote HydroLight/Anders Austegard. The ELC is connected to a synchronous generator on the Cross flow turbine test rig. The controller uses phase angle regulation to control the power output of the system, by triggering three 2kW heating elements (dump loads). A quantitative analysis will be performed by logging output electrical power + generator voltage and compare it with dump load voltage. Since electrical equipment is sensitive to changes in frequency, the generator frequency is logged. Several stress tests will be performed in order to check the stability and the response time of the system. The experiment is set up in the Waterpower Laboratory. The setup arrangement is duplex; the cross flow turbine test rig and the ELC-system. The cross flow turbine test rig is composed of piping network to conduct water from the pump, through the pressure tank and into the Cross flow turbine rig. The installed cross flow turbine is made up of a nozzle, runner, and housing. A screw handle is used to adjust the nozzle opening and to control the flow to the runner. The flow is changed by increasing or decreasing the pump speed. To convert the mechanical energy to electrical energy, a synchronous generator is used. The Cross flow turbine is connected to the generator via a belt drive. The ELC-system is composed of an ELC-cabinet, a dump load system and a consumption load system. The ELC is connected to the generator (220V AC) and uses generator voltage as input signal. Four heating elements (3x 2kW + 1x 1kW) with switches are used as consumption load. The dump load system consists of three heating elements with capacity of 2kW each. Both dump load- and consumption load-systems are submerged into the lower reservoir. They are installed in a waterproof environment to prevent short circuits. A verified cabinet is used to protect the electrical components in the ELC. The switches are installed on the front panel of the cabinet. To log the generator and dump load voltage, a data aquistion unit from National Instrument (NI9225) is used. The instrument has a range of -300 - +300V. In order to control the flow and pressure at the inlet of the turbine, an electromagnetic flow meter and a pressure transducer are assembled to the test rig. Power output is determined by measuring voltage and current from the generator. (P=U*I) The following are added to this report as Attachment A: Process and Instrumentation Diagram (PID)
Drawings and photos describing the setup.
3
6 EVACUATION FROM THE EXPERIMENTAL AREA
Evacuate at signal from the alarm system or local gas alarms with its own local alert with sound and light outside the room in question, see 6.2 Evacuation from the rigging area takes place through the marked emergency exits to the assembly point, (corner of Old Chemistry Kjelhuset or parking 1a-b.) Action on rig before evacuation: Use emergency switch to stop the pump and close windows.
7 WARNING
7.1 Before experiments
Send an e-mail with information about the planned experiment to: Liste [email protected] The e-mail should contain the following items:
• Name of responsible person: • Experimental setup/rig: • Start Experiments: (date and time) • Stop Experiments: (date and time)
You must get the approval back from the laboratory management before start up. All running experiments are notified in the activity calendar for the lab to be sure they are coordinated with other activity.
7.2 Non-conformance
FIRE If you are NOT able to extinguish the fire, activate the nearest fire alarm and evacuate area. Be then available for fire brigade and building caretaker to detect fire place. If possible, notify:
NTNU SINTEF
Morten Grønli, Mob: 918 97 515 Harald Mæhlum, Mob: 930 14 986
Olav Bolland: Mob: 918 97 209 Anne Karin T. Hemmingsen Mob: 930 19 669
NTNU – SINTEF Beredskapstelefon 800 80 388
GAS ALARM If a gas alarm occurs, close gas bottles immediately and ventilate the area. If the level of the gas concentration does not decrease within a reasonable time, activate the fire alarm and evacuate the lab. Designated personnel or fire department checks the leak to determine whether it is possible to seal the leak and ventilate the area in a responsible manner.
PERSONAL INJURY First aid kit in the fire / first aid stations
4
Shout for help
Start life-saving first aid
CALL 113 if there is any doubt whether there is a serious injury OTHER NON-CONFORMANCE (AVVIK) NTNU: You will find the reporting form for non-conformance on: https://innsida.ntnu.no/wiki/-/wiki/Norsk/Melde+avvik SINTEF: Synergi
8 ASSESSMENT OF TECHNICAL SAFETY
8.1 HAZOP
The experiment set up is divided into the following nodes:
Node 1 Pressure tank
Node 2 Cross flow turbine with generator
Node 3 ELC
Node 4 Heating elements
Attachments: Form: HAZOP Template Conclusion: Safety taken care of
8.2 Flammable, reactive and pressurized substances and gas
Are any flammable, reactive and pressurized substances and gases in use?
YES Pressurised water
Attachments: None Conclusion: This experiment will be carried out using low head values (up to 5 mWc). The consequences from pressurised water are therefore small.
8.3 Pressurized equipment
Is any pressurized equipment in use?
YES Pump, pressure tank and pipes
Attachments: None Conclusion: The pump, pressure tank and the pipeline (except the last pipe from V23 to Crossflow turbine) has been pressure tested. Even though the pipe has not been pressure tested, since the experiment will use low values of head, the stress levels in the pipe will be low.
5
8.4 Effects on the environment (emissions, noise, temperature, vibration, smell)
Will the experiments generate emission of smoke, gas, odour or unusual waste? Is there a need for a discharge permit, extraordinary measures?
NO
8.5 Radiation
NO
8.6 Chemicals
NO
8.7 Electricity safety (deviations from the norms/standards)
NO
9 ASSESSMENT OF OPERATIONAL SAFETY
Ensure that the procedures cover all identified risk factors that must be taken care of. Ensure that the operators and technical performance have sufficient expertise.
9.1 Procedure HAZOP
The method is a procedure to identify causes and sources of danger to operational problems. Attachments: HAZOP Procedure
Conclusion:
Operation and emergency shutdown procedure The operating procedure is a checklist that must be filled out for each experiment. Emergency procedure should attempt to set the experiment setup in a harmless state by unforeseen events. Attachments: Procedure for running experiments
Emergency shutdown procedure
9.2 Training of operators
A document showing training plan for operators
What are the requirements for the training of operators? • What it takes to be an independent operator • Job Description for operators Attachments: Training program for operators
6
9.3 Technical modifications
Technical modifications made by the Operator o (for example: Replacement of components, equal to equal)
• Technical modifications that must be made by Technical staff: o (for example, modification of pressure equipment).
• What technical modifications give a need for a new risk assessment; (by changing the risk picture)?
Conclusion:
If some components fail and need to be changed, experiment will stop and technical staff will be contacted. If larger modifications are necessary, a new risk assessment will be carried out.
9.4 Personal protective equipment
It is mandatory use of eye protection in the rig zone It is mandatory use of protective shoes in the rig zone. Use gloves when there is opportunity for contact with hot/cold surfaces. Use of respiratory protection apparatus
Conclusion: Protective eyewear will be used at all times when the experiment is in progress. The goggles are found in two boxes in Laboratory: one box is placed just at the entrance (Entrance Door to Room 21 of the Waterpower Main Laboratory Section) and the other box is placed close to the emergency exit door to the main entrance of the Water power Laboratory. Since water is conductive, it is important to keep hands dry when working in the lab to minimize the risk of electric shock.
9.4.1 General Safety
The area around the staging attempts shielded.
Gantry crane and truck driving should not take place close to the experiment.
Gas cylinders shall be placed in an approved carrier with shut-off valve within easy reach.
Monitoring, can experiment run unattended, how should monitoring be?
Conclusion:
A barrier will be installed around the ELC, heating elements and generator during testing. The experiment should not be run without being attended by the operators. The operators should monitor the progress of the experiment at all times. The rotating shafts (turbine and generator shafts + belt drive) should not be touched and to avoid this, a cover has been installed. There is a possibility of water spillage on the floor (which is along one of the emergency escape routes in the Laboratory) and should it happen, then operators should mop the water spillage after the experiment. If spillage accumulates during the experiment, then the experiment should be stopped until the water is mopped. Electric operated vacuum water mopper is available in the Laboratory base floor where the experiment test rig is.
7
Is Operator allowed to leave during the experiment? The operators cannot leave the test rig while this experiment is in progress. As already stated above, the operator should monitor the progress and pay attention to the quality of the experiment process at all times. If it happens that the experiment is not progressing as envisaged and that danger to the machine units (turbine and generator) and to operators is most likely, then the experiment should be stopped using the emergency shutdown procedure.
9.5 Safety equipment
• Warning signs, see the Regulations on Safety signs and signalling in the workplace
9.6 Special preparations
For example: Monitoring.
Safety preparedness.
Safe Job Analysis of modifications, (SJA)
Working at heights
Flammable / toxic gases or chemicals
10 QUANTIFYING OF RISK - RISK MATRIX
The risk matrix will provide visualization and an overview of activity risks so that management and users get the most complete picture of risk factors.
IDnr Aktivitet-hendelse Frekv-Sans Kons RV
1 Rotating shaft and belt drive, danger of contact 1 C C1
2 Much noise, people without protective gear enter the rig site
1 A B1
3 Splashing water 3 A A3
4 Overheating electronic equipment 2 C C2
5 Short circuits on electronic components 1 B C1
Conclusion: The risks associated to this experiment are acceptable. The most risk-associated part of the experiment is the performance of the electronic components in the ELC. In order to reduce the risk according Idnr.4, the temperature inside the cabinet is measured and the operators have to pay attention if temperature changes rapidly. The fire extinguisher is located by the entrance door in the laboratory. To reduce risk according Idnr 1, a cover has been installed to avoid contact. All electronic components in the setup have been controlled by verified personnel. Nevertheless, it will always be a risk according short circuits in components since it is high voltage and components may change behaviour during the experiment.
8
11 REGULATIONS AND GUIDELINES
Se http://www.arbeidstilsynet.no/regelverk/index.html
Lov om tilsyn med elektriske anlegg og elektrisk utstyr (1929)
Arbeidsmiljøloven
Forskrift om systematisk helse-, miljø- og sikkerhetsarbeid (HMS Internkontrollforskrift)
Forskrift om sikkerhet ved arbeid og drift av elektriske anlegg (FSE 2006)
Forskrift om elektriske forsyningsanlegg (FEF 2006)
Forskrift om utstyr og sikkerhetssystem til bruk i eksplosjonsfarlig område NEK 420
Forskrift om håndtering av brannfarlig, reaksjonsfarlig og trykksatt stoff samt utstyr og anlegg som benyttes ved håndteringen
Forskrift om Håndtering av eksplosjonsfarlig stoff
Forskrift om bruk av arbeidsutstyr.
Forskrift om Arbeidsplasser og arbeidslokaler
Forskrift om Bruk av personlig verneutstyr på arbeidsplassen
Forskrift om Helse og sikkerhet i eksplosjonsfarlige atmosfærer
Forskrift om Høytrykksspyling
Forskrift om Maskiner
Forskrift om Sikkerhetsskilting og signalgivning på arbeidsplassen
Forskrift om Stillaser, stiger og arbeid på tak m.m.
Forskrift om Sveising, termisk skjæring, termisk sprøyting, kullbuemeisling, lodding og sliping (varmt arbeid)
Forskrift om Tekniske innretninger
Forskrift om Tungt og ensformig arbeid
Forskrift om Vern mot eksponering for kjemikalier på arbeidsplassen (Kjemikalieforskriften)
Forskrift om Vern mot kunstig optisk stråling på arbeidsplassen
Forskrift om Vern mot mekaniske vibrasjoner
Forskrift om Vern mot støy på arbeidsplassen Veiledninger fra arbeidstilsynet se: http://www.arbeidstilsynet.no/regelverk/veiledninger.html
9
12 DOCUMENTATION
Tegninger, foto, beskrivelser av forsøksoppsetningen
Hazop_mal
Sertifikat for trykkpåkjent utstyr
Håndtering avfall i NTNU
Sikker bruk av LASERE, retningslinje
HAZOP_MAL_Prosedyre
Forsøksprosedyre
Opplæringsplan for operatører
Skjema for sikker jobb analyse, (SJA)
Apparaturkortet
Forsøk pågår kort
13 GUIDANCE TO RISK ASSESSMENT TEMPLATE
Chapter 7 Assessment of technical safety. Ensure that the design of the experiment set up is optimized in terms of technical safety. Identifying risk factors related to the selected design, and possibly to initiate re-design to ensure that risk is eliminated as much as possible through technical security. This should describe what the experimental setup actually are able to manage and acceptance for emission.
7.1 HAZOP The experimental set up is divided into nodes (eg motor unit, pump unit, cooling unit.). By using guidewords to identify causes, consequences and safeguards, recommendations and conclusions are made according to if necessary safety is obtained. When actions are performed the HAZOP is completed. (e.g. "No flow", cause: the pipe is deformed, consequence: pump runs hot, precaution: measurement of flow with a link to the emergency or if the consequence is not critical used manual monitoring and are written into the operational procedure.)
7.2 Flammable, reactive and pressurized substances and gas. According to the Regulations for handling of flammable, reactive and pressurized substances and equipment and facilities used for this:
Flammable material: Solid, liquid or gaseous substance, preparation, and substance with occurrence or combination of these conditions, by its flash point, contact with other substances, pressure, temperature or other chemical properties represent a danger of fire.
Reactive substances: Solid, liquid, or gaseous substances, preparations and substances that occur in combinations of these conditions, which on contact with water, by its pressure, temperature or chemical conditions, represents a potentially dangerous reaction, explosion or release of hazardous gas, steam, dust or fog.
Pressurized : Other solid, liquid or gaseous substance or mixes having fire or hazardous material response, when under pressure, and thus may represent a risk of uncontrolled
10
emissions
Further criteria for the classification of flammable, reactive and pressurized substances are set out in Annex 1 of the Guide to the Regulations "Flammable, reactive and pressurized substances" http://www.dsb.no/Global/Publikasjoner/2009/Veiledning/Generell%20veiledning.pdf http://www.dsb.no/Global/Publikasjoner/2010/Tema/Temaveiledning_bruk_av_farlig_stoff_Del_1.pdf
Experiment setup area should be reviewed with respect to the assessment of Ex zone • Zone 0: Always explosive atmosphere, such as inside the tank with gas, flammable liquid. • Zone 1: Primary zone, sometimes explosive atmosphere such as a complete drain point • Zone 2: secondary discharge could cause an explosive atmosphere by accident, such as flanges, valves and connection points
7.4 Effects on the environment With pollution means: bringing solids, liquid or gas to air, water or ground, noise and vibrations, influence of temperature that may cause damage or inconvenience effect to the environment. Regulations: http://www.lovdata.no/all/hl-19810313-006.html#6 NTNU guidance to handling of waste:http://www.ntnu.no/hms/retningslinjer/HMSR18B.pdf
7.5 Radiation Definition of radiation
Ionizing radiation: Electromagnetic radiation (in radiation issues with wawelength <100 nm) or rapid atomic particles (e.g. alpha and beta particles) with the ability to stream ionized atoms or molecules.
Non ionizing radiation: Electromagnetic radiation (wavelength >100 nm), og ultrasound1 with small or no capability to ionize.
Radiation sources: All ionizing and powerful non-ionizing radiation sources.
Ionizing radiation sources: Sources giving ionizing radiation e.g. all types of radiation sources, x-ray, and electron microscopes.
Powerful non ionizing radiation sources: Sources giving powerful non ionizing radiation which can harm health and/or environment, e.g. class 3B and 4. MR2 systems, UVC3 sources, powerful IR sources4.
1Ultrasound is an acoustic radiation ("sound") over the audible frequency range (> 20 kHz). In radiation protection regulations are referred to ultrasound with electromagnetic non-ionizing radiation.
2MR (e.g. NMR) - nuclear magnetic resonance method that is used to "depict" inner structures of different materials.
3UVC is electromagnetic radiation in the wavelength range 100-280 nm.
4IR is electromagnetic radiation in the wavelength range 700 nm - 1 mm.
For each laser there should be an information binder (HMSRV3404B) which shall include: • General information • Name of the instrument manager, deputy, and local radiation protection coordinator • Key data on the apparatus • Instrument-specific documentation
11
• References to (or copies of) data sheets, radiation protection regulations, etc. • Assessments of risk factors • Instructions for users • Instructions for practical use, startup, operation, shutdown, safety precautions, logging,
locking, or use of radiation sensor, etc. • Emergency procedures
See NTNU for laser: http://www.ntnu.no/hms/retningslinjer/HMSR34B.pdf
7.6 The use and handling of chemicals. In the meaning chemicals, a element that can pose a danger to employee safety and health See: http://www.lovdata.no/cgi-wift/ldles?doc=/sf/sf/sf-20010430-0443.html Safety datasheet is to be kept in the HSE binder for the experiment set up and registered in the database for chemicals.
Chapter 8 Assessment of operational procedures. Ensures that established procedures meet all identified risk factors that must be taken care of through operational barriers and that the operators and technical performance have sufficient expertise.
8.1 Procedure Hazop Procedural HAZOP is a systematic review of the current procedure, using the fixed HAZOP methodology and defined guidewords. The procedure is broken into individual operations (nodes) and analyzed using guidewords to identify possible nonconformity, confusion or sources of inadequate performance and failure.
8.2 Procedure for running experiments and emergency shutdown. Have to be prepared for all experiment setups. The operating procedure has to describe stepwise preparation, startup, during and ending conditions of an experiment. The procedure should describe the assumptions and conditions for starting, operating parameters with the deviation allowed before aborting the experiment and the condition of the rig to be abandoned. Emergency procedure describes how an emergency shutdown have to be done, (conducted by the uninitiated), what happens when emergency shutdown, is activated. (electricity / gas supply) and which events will activate the emergency shutdown (fire, leakage).
Chapter 9 Quantifying of RISK Quantifying of the residue hazards, Risk matrix To illustrate the overall risk, compared to the risk assessment, each activity is plotted with values for the probability and consequence into the matrix. Use task IDnr. Example: If activity IDnr. 1 has been given a probability 3 and D for consequence the risk value become D3, red. This is done for all activities giving them risk values. In the matrix are different degrees of risk highlighted in red, yellow or green. When an activity ends up on a red risk (= unacceptable risk), risk reducing action has to be taken
CO
NSE
QU
ENS
ES
Svært alvorlig
E1 E2 E3 E4 E5
Alvorlig D1 D2 D3 D4 D5
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Moderat C1 C2 C3 C4 C5
Liten B1 B2 B3 B4 B5
Svært liten
A1 A2 A3 A4 A5
Svært liten Liten Middels Stor Svært Stor
PROBABILITY
The principle of the acceptance criterion. Explanation of the colors used in the matrix
Colour Description
Red Unacceptable risk Action has to be taken to reduce risk
Yellow Assessment area. Actions has to be considered
Green Acceptable risk. Action can be taken based on other criteria
Attachment to Risk Assessment report
Cross flow turbine connected to ELC
Prosjektnavn Crossflow Turbine connected to ELC
Apparatur Crossflow Turbine and ELC
Enhet NTNU
Apparaturansvarlig Bård Brandåstrø
Prosjektleder Torbjørn Nielsen
HMS-koordinator Morten Grønli
HMS-ansvarlig (linjeleder) Olav Bolland
Plassering Waterpower Laboratory
Romnummer Room 21
Risikovurdering utført av Øystein Sveinsgjerd Hveem, Magni Fjørtoft Svarstad, Kristin Gjevik, Chiyembekezo Kaunda, Peter Joachim Gogstad, Bård Brandåstrø
TABLE OF CONTENTS
ATTACHMENT A: PROCESS AND INSTRUMENTATION DIAGRAM .............................................. 1
ATTACHMENT B: HAZOP TEMPLATE .......................................................................................... 8
ATTACHMENT C: TEST CERTIFICATE FOR LOCAL PRESSURE TESTING ....................................... 1
ATTACHMENT D: HAZOP PROCEDURE (TEMPLATE) .................................................................. 1
ATTACHMENT E: PROCEDURE FOR RUNNING EXPERIMENTS.................................................... 1
ATTACHMENT F: TRAINING OF OPERATORS .............................................................................. 5
ATTACHMENT G: FORM FOR SAFE JOB ANALYSIS...................................................................... 6
APPARATURKORT / UNITCARD ................................................................................................... 8
FORSØK PÅGÅR /EXPERIMENT IN PROGRESS ............................................................................ 9
1
ATTACHMENT A: PROCESS AND INSTRUMENTATION DIAGRAM
Introduction The following are listed in Attachment A to further describe experimental setup of the the Crossflow Turbine rig connected to the ELC.
Process and Instrument Diagram (PID)
Figure 1: Waterflow system for the experiment showing arrangement and position of Crossflow Turbine rig with respect to pumps, pressurised tank and pipe network.
Pressure tank
Crossflow turbine
Flow meter
Basement pumps
Discharge to lower reservoir
Pressure taps
2
Figure 1: Principle of experimental setup
3
Electronic load controller (ELC)
Cross flow turbine test rig
Location of heating elements
Switches for heating elements
Figure 2: Cross flow turbine connected to ELC with 7 heating elements submerged in lower reservoir.
4
Cross flow turbine
Synchronous generator
Belt drive with cover
Manual handle for guide vane opening
Figure 2: Experimental setup: Cross flow turbine test rig
Figure 3: Escape valve on top of pressure tank
Figure 4: Part of the piping network to the Cross flow Turbine Test Rig showing manual operated valve V23 and valve V8.
V8
V23 Pressure tank
Escape valve
5
Figure 5: Inside ELC
Figure 6: Setup of heating elements
Fuses
Printed circuit board
Heat sinks Triacs
Location for temp sensor
Input generator voltage (AC)
Wiring to seven heating elements
Figure 7: Heating element
6
Figure 11: Pressure taps installed perpendicular to the pipe at the entrance of the turbine. Notice the tubes carrying water to the pressure transducer. The when the experiment is running, the tube must be checked of presence of air bubbles. Presence of air bubbles in water in the tube affects the quality of pressure signal from the transducer and gives incorrect differential pressure. The entrained air bubbles are removed from the tubes by bleeding.
Figure 9: Temperature measurement for water Figure 8: Installed electromagnetic flow rate meter. Figure 10: Optical measurement of turbine
speed
7
Figure 13: Amp clamp meter used together with Voltech PM3000A
Figure 12: Instrument used for measuring voltage and current. From these values, power output is determined.
8
Attachment B: HAZOP template
Project: Cross flow turbine connected to ELC Node: 1 – Pressure tank
Page 1
Ref Guideword Causes Consequences Safeguards Recommendations Action Date/Sign
No flow Closed valve No consequence Open valve
Reverse flow High pressure in the tank
Increase pump speed
More level Too high pump speed
Overflow pipe line in the pressure tank is
installed
Less level Low pump speed
More pressure Too high pump speed
Less pressure Low pump speed
Loss of pump power
No flow
9
Project: Cross flow turbine connected to ELC Node: 2 – Crossflow turbine rig with generator
Page 2
Ref Guideword Causes Consequences Safeguards Recommendations Action Date/Sign
No flow Closed valve No consequence Open screw valve
Reverse flow Not possible
More flow Too high pump speed Increased flow leakage to the floor
Reduce pump speed.
Less flow Low pump speed
More pressure Too high pump speed Increased flow leakage to the floor
Reduce pump speed
Less pressure Low pump speed
Loss of pump power
No flow
Loss of load Generator disconnected
Rotational speed of turbine increases
Emergency switch for disconnecting the pump is installed
Reduce pump speed gradually and stop the pump
10
Project: Cross flow turbine connected to ELC Node: 3 – ELC
Page 3
Ref Guideword Causes Consequences Safeguards Recommendations Action Date/Sign
Temperature in ELC increases
rapidly
Short circuit or too bad ventilation
Overheating and damaging electronic
components
Fire extinguisher is located close to the
test rig
Use emergency shutdown switch if
critical
Stop experiment. Open ELC-cabinet
and look for damaged
components
Smell of burning Overheating or short circuits of electronic
components
Damage electronic components
Fire extinguisher is located close to the
test rig
Use emergency shutdown switch if
critical
Stop experiment. Open ELC-cabinet
and look for damaged
components
Fuses to heating elements brakes
Possibly short circuit on heating element
terminal
Stop experiment and control
heating element
Fuses between generator and
ELC brakes
Possibly overvoltage from generator
Load disconnected and turbine speed increases rapidly
Emergency switch for shutdown pump
is installed
Stop experiment by reducing
pump speed and close valves.
11
Project: Cross flow turbine connected to ELC Node: 4 – Heating elements
Page 4
Ref Guideword Causes Consequences Safeguards Recommendations Action Date/Sign
Dryheating Low waterlevel in reservoir
Damage elements Stop experiment and control level in
reservoir.
Submerge element
Short circuit on terminal
Moisture/water leakage into
terminals
Elements stop heating
Stop experiment
1
ATTACHMENT C: TEST CERTIFICATE FOR LOCAL PRESSURE TESTING
Trykkpåkjent utstyr:
Benyttes i rigg:
Design trykk for utstyr (bara):
Maksimum tillatt trykk (bara): (i.e. burst pressure om kjent)
Maksimum driftstrykk i denne rigg:
Prøvetrykket skal fastlegges i følge standarden og med hensyn til maksimum tillatt trykk.
Prøvetrykk (bara):
X maksimum driftstrykk: I følge standard
Test medium:
Temperatur (°C)
Start tid: Trykk (bara):
Slutt tid: Trykk (bara):
Maksimum driftstrykk i denne rigg:
Eventuelle repetisjoner fra atm. trykk til maksimum prøvetrykk:…………….
Test trykket, dato for testing og maksimum tillatt driftstrykk skal markers på (skilt eller innslått) Sted og dato Signatur
1
ATTACHMENT D: HAZOP PROCEDURE (TEMPLATE)
Project: Node: 1
Page
Ref# Guideword Causes Consequences Safeguards Recommendations Action Date/Sign
Not clear procedure
Procedure is to ambitious, or confusingly
Step in the wrong place
The procedure can lead to actions done in the wrong pattern or sequence
Wrong actions
Procedure improperly specified
Incorrect information
Information provided in advance of the specified action is wrong
Step missing
Missing step, or step requires too much of operator
Step unsucessful Step has a high probability of failure
Influence and effects from other
Procedure's performance can be affected by other sources
1
ATTACHMENT E: PROCEDURE FOR RUNNING EXPERIMENTS
Prosjekt Crossflow Turbine
Dato/Signatur
Apparatur Crossflow Turbine
Prosjektleder Torbjørn Nielsen
Operatører: Øystein Sveinsgjerd Hveem
Magni Fjørtoft Svarstad
Kristin Gjevik
Chiyembekezo Kaunda
Conditions for the experiment: Completed
Experiments should be run in normal working hours, 08:00-16:00 during winter time and 08.00-15.00 during summer time. Experiments outside normal working hours shall be approved.
One person must always be present while running experiments, and should be approved as an experimental leader.
An early warning is given according to the lab rules, and accepted by authorized personnel.
Be sure that everyone taking part of the experiment is wearing the necessary protecting equipment and is aware of the shutdown procedure and escape routes.
Preparations Carried out
1. Make a walk-through inspection in the laboratory, paying attention to
any hazard. Clear all of the identified hazards before starting the
experiment. Close all drain pipes. Check that all instrumentations to
the rig are intact. Open the ELC cabinet and look for any changes in
components (smell of burning, open wires etc.). Set up barriers
around experimental setup. Control the level in the lower reservoir
and verify that all heating elements are submerged. In the control
room, check that there are no alerts in the lab.
2. If no extraordinary hazards are observed, the experiment is ready to
be started. Turn on the frequency converter for the pump located in
the pump room in the basement. Turn the switch to START. Keep it
there for a while (a second or so) and then let it go so that it stops at
position marked 1.
3. On the Cross flow Turbine test rig, post the “Experiment in progress” card.
2
Start up procedure Filling the pressure tank
1. Check that the annular valve is closed at the bottom of the pressure
tank. Also check that the manual valve to the Crossflow turbine V23 is
closed.
2. Control room: use the PLC and identify the loop to use for the
Crossflow turbine test rig. Check that valves V9 and V29 are closed.
3. Check the water level in the pressure tank.
4. Open the manual valve on top of the pressure tank
5. Startup pump using the PLC in the control room by gradually
increasing the speed to about 325 rpm. Check the water level as the
pump is running. When the water the level has stabilized at the set
point, then close the manual valve on top of the pressure tank.
Startup Crossflow turbine and ELC
1. Go down to the Cross flow turbine test rig. Launch the LabView
Program – “CrossflowTurbine” on the main computer and
“ELC_Logging” on the second computer.
2. Switch the dump loads ON
3. Check that the guide vane on the Cross flow turbine is open. Open
valve V8 (out from pressure tank) using the PLC. Open the manual
valve V23 slowly in order to get a smooth acceleration of the turbine.
Bleed the pipes for the pressure transducer while the turbine is
running.
4. Start choosing an operational point for the cross flow turbine, by
changing (head and cross flow guide vane opening). The ELC has a
capacity of 6kW so the two parameters; pump speed and nozzle
opening, have to be set rather low to avoid damage on the ELC. An
operational point with a net head of 5m, nozzle opening of 80% and a
rotational speed on the cross flow turbine of 400-450 RPM is used in
order to get a power output of 6kW. Guide vane opening is set by
using the manual valve (on top of the cross flow turbine) to the
marked opening (percentage value). Rotational speed of the turbine is
set with pump speed and flow.
5. The rig is now ready for doing measurements.
3
Experiment
Controlling LEDS and components
1. Check that all of the three large LED lights. These monitor that the
three phases on the generator are connected.
2. Reset the fuses. All energy should then still be diverted into the dump
loads. (Since consumption load is 0)
3. Switch on more consumption loads and control that all the four small
LEDs are working properly.
4. Run with only dump loads connected for two hours and look for
overheating and failure in components.
Rapid off-load-situation
1. Switch on 6 kW consumption loads.
2. Switch all consumption loads off. Log response in generator voltage.
Rapid on-load-situation
1. Keep only dump loads connected (6kW).
2. Switch 6 kW consumption loads on. Log response in generator
voltage.
Overload situation
1. Switch on 6kW consumption loads.
2. Switch on the extra 1kW heating element and log response in voltage
Run-away situation
1. Switch off all consumption loads.
2. Brake fuses from generator and simulate a disconnection of load to
generator.
3. When a constant speed is obtained, reduce the pump speed and do
the stop procedure.
4
Measurements
1. From the LabView-program “ELC_Logging” , generator voltage, dump
load voltage, trigger angle and frequency are measured and logged
during the experiments. In “CrossflowTurbine” , hydraulic power is
obtained from logged values of discharge, water temperature and
pressure.
Shutdown procedure
1. Reduce the pump speed slowly to 320 RPM by a decrease of 10 rpm
2. Close V8 from pressure tank.
3. When pipes in cross flow loop are empty for water: Close V23
manually
4. Check for over-pressure in the pressure tank
5. Open the manual valve on top of the pressure tank
6. Reduce the pump speed further to 100 rpm by a decrease of 10.
7. Stop the pump
8. Stop the frequency converter by turning the switch to 0
End of experiment
1. Tidy and cleanup work areas and equipment.
2. Remove all obstructions/barriers/signs around the experiment.
3. Return equipment and systems back to their normal operation settings
Emergency Shutdown procedure
If an emergency situation arises, switch off the power to the pump using the
emergency switch which is located inside the Control Room or using the
emergency switch that is located in the base floor close to the pressure
transducer.
To reflect on before the next experiment and experience useful for others
Was the experiment completed as planned and on scheduled in professional terms?
Was the competence which was needed for security and completion of the experiment available to you?
Do you have any information/ knowledge from the experiment that you should document and share with fellow colleagues?
5
ATTACHMENT F: TRAINING OF OPERATORS
Prosjekt Crossflow Turbine
Dato/Signatur
Apparatur Crossflow Turbine and Electronic Load Controller
Prosjektleder Torbjørn Nielsen
Knowledge about EPT LAB in general
Lab - Access -routines and rules -working hour
Knowledge about the evacuation procedures.
Activity calendar for the Lab
Early warning, Liste [email protected]
Knowledge about the experiments
Procedures for the experiments
Emergency shutdown.
Nearest fire and first aid station.
I hereby declare that I have read and understood the regulatory requirements has received appropriate training to run this experiment and are aware of my personal responsibility by working in EPT laboratories.
Name Signature
Øystein Sveinsgjerd Hveem
Magni Fjørtoft Svarstad
Chiyembekezo Kaunda
6
ATTACHMENT G: FORM FOR SAFE JOB ANALYSIS
SJA name:
Date: Location:
Mark for completed checklist:
Participators:
SJA-responsible:
Specification of work (What and how?):
Risks associated with the work:
Safeguards: (plan for actions, see next page):
Conclusions/comments:
Recommended/approved Date/Signature: Recommended/approved Date/Signature:
SJA-responsible: HSE responsible:
Responsible for work: Other, (position):
7
HSE aspect Yes No NA Comments / actions Resp.
Documentation, experience, qualifications
Known operation or work?
Knowledge of experiences / incidents from similar operations?
Necessary personnel?
Communication and coordinating
Potential conflicts with other operations?
Handling of an eventually incident (alarm, evacuation)?
Need for extra assistance / watch?
Working area
Unusual working position
Work in tanks, manhole?
Work in ditch, shaft or pit?
Clean and tidy?
Protective equipment beyond the personal?
Weather, wind, visibility, lighting, ventilation?
Usage of scaffolding/lifts/belts/ straps, anti-falling device?
Work at hights?
Ionizing radiation?
Influence of escape routes?
Chemical hazards
Usage of hazardous/toxic/corrosive chemicals?
Usage of flammable or explosive chemicals?
Risk assessment of usage?
Biological materials/substances?
Dust/asbestos/dust from insulation?
Mechanical hazards
Stability/strength/tension?
Crush/clamp/cut/hit?
Dust/pressure/temperature?
Handling of waste disposal?
Need of special tools?
Electrical hazards
Current/Voltage/over 1000V?
Current surge, short circuit?
Loss of current supply?
Area
Need for inspection?
Marking/system of signs/rope off?
Environmental consequences?
Key physical security systems
Work on or demounting of safety systems?
Other
8
APPARATURKORT / UNITCARD
Dette kortet SKAL henges godt synlig på apparaturen! This card MUST be posted on a visible place on the unit!
Apparatur (Unit)
Cross flow turbine connected to ELC
Prosjektleder (Project Leader) Telefon mobil/privat (Phone no. mobile/private)
Torbjørn Nielsen 91897572
Apparaturansvarlig (Unit Responsible) Telefon mobil/privat (Phone no. mobile/private)
Bård Brandåstrø 91897257
Sikkerhetsrisikoer (Safety hazards)
Splashing Water
Rotating equipment
Overheating of electronic components
Short circuits on components Sikkerhetsregler (Safety rules)
Set up barriers
Wear safety glasses
Do no touch rotating shaft
Nødstopp prosedyre (Emergency shutdown) Shut down feed pumps. The Emergency switch located in the Main Laboratory Control Room and in the Laboratory First Floor
Her finner du (Here you will find):
Prosedyrer (Procedures) In a Laboratory Book
Bruksanvisning (Users manual) In a Laboratory Book
Nærmeste (Nearest)
Brannslukningsapparat (fire extinguisher) Near the entrance\exit
Førstehjelpsskap (first aid cabinet) Near the entrance\exit
NTNU Institutt for energi og prosessteknikk
Dato
Signert
9
FORSØK PÅGÅR /EXPERIMENT IN PROGRESS
Dette kortet SKAL henges opp før forsøk kan starte! This card MUST be posted on the unit before the experiment
startup!
Apparatur (Unit)
Cross flow turbine connected to ELC
Prosjektleder (Project Leader) Telefon mobil/privat (Phone no. mobile/private)
Torbjørn Nielsen 91897572
Apparaturansvarlig (Unit Responsible) Telefon mobil/privat (Phone no. mobile/private)
Bård Brandåstrø 91897257
Godkjente operatører (Approved Operators) Telefon mobil/privat (Phone no. mobile/private)
Øystein Sveinsgjerd Hveem, Magni Fjørtoft Svarstad, Kristin Gjevik, Chiyembekezo Kaunda
99406075 41641665 98809726 40299725
Prosjekt (Project)
Crossflow Turbine connected to ELC
Forsøkstid / Experimental time (start ‐ stop)
05.09.2013 - 30.09.2013
Kort beskrivelse av forsøket og relaterte farer (Short description of the experiment and related hazards)
The experiment is analyzing the performance of an electronic load controller in connection with a cross flow turbine and a generator. The related hazards are:
Water splash
Rotating shaft
Overheating of electronic components
Short circuits on electronic components
NTNU Institutt for energi og prosessteknikk
Dato
Signert